CN1841592A - Multilayer capacitor - Google Patents
Multilayer capacitor Download PDFInfo
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- CN1841592A CN1841592A CNA2006100664934A CN200610066493A CN1841592A CN 1841592 A CN1841592 A CN 1841592A CN A2006100664934 A CNA2006100664934 A CN A2006100664934A CN 200610066493 A CN200610066493 A CN 200610066493A CN 1841592 A CN1841592 A CN 1841592A
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- 239000003990 capacitor Substances 0.000 title claims abstract description 383
- 239000004020 conductor Substances 0.000 claims abstract description 593
- 238000009413 insulation Methods 0.000 claims description 7
- 238000010030 laminating Methods 0.000 abstract 2
- 239000000758 substrate Substances 0.000 description 49
- 230000000875 corresponding effect Effects 0.000 description 32
- 238000009434 installation Methods 0.000 description 23
- 238000010586 diagram Methods 0.000 description 18
- 230000002596 correlated effect Effects 0.000 description 7
- 230000008878 coupling Effects 0.000 description 4
- 238000010168 coupling process Methods 0.000 description 4
- 238000005859 coupling reaction Methods 0.000 description 4
- 238000000034 method Methods 0.000 description 4
- 230000000007 visual effect Effects 0.000 description 4
- 238000011160 research Methods 0.000 description 3
- 230000012447 hatching Effects 0.000 description 2
- 230000015572 biosynthetic process Effects 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000012545 processing Methods 0.000 description 1
- 238000012797 qualification Methods 0.000 description 1
- 230000003252 repetitive effect Effects 0.000 description 1
- 230000003068 static effect Effects 0.000 description 1
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01G—CAPACITORS; CAPACITORS, RECTIFIERS, DETECTORS, SWITCHING DEVICES, LIGHT-SENSITIVE OR TEMPERATURE-SENSITIVE DEVICES OF THE ELECTROLYTIC TYPE
- H01G4/00—Fixed capacitors; Processes of their manufacture
- H01G4/33—Thin- or thick-film capacitors
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01G—CAPACITORS; CAPACITORS, RECTIFIERS, DETECTORS, SWITCHING DEVICES, LIGHT-SENSITIVE OR TEMPERATURE-SENSITIVE DEVICES OF THE ELECTROLYTIC TYPE
- H01G4/00—Fixed capacitors; Processes of their manufacture
- H01G4/002—Details
- H01G4/228—Terminals
- H01G4/232—Terminals electrically connecting two or more layers of a stacked or rolled capacitor
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01G—CAPACITORS; CAPACITORS, RECTIFIERS, DETECTORS, SWITCHING DEVICES, LIGHT-SENSITIVE OR TEMPERATURE-SENSITIVE DEVICES OF THE ELECTROLYTIC TYPE
- H01G4/00—Fixed capacitors; Processes of their manufacture
- H01G4/002—Details
- H01G4/255—Means for correcting the capacitance value
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01G—CAPACITORS; CAPACITORS, RECTIFIERS, DETECTORS, SWITCHING DEVICES, LIGHT-SENSITIVE OR TEMPERATURE-SENSITIVE DEVICES OF THE ELECTROLYTIC TYPE
- H01G4/00—Fixed capacitors; Processes of their manufacture
- H01G4/30—Stacked capacitors
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- Microelectronics & Electronic Packaging (AREA)
- Manufacturing & Machinery (AREA)
- Fixed Capacitors And Capacitor Manufacturing Machines (AREA)
- Ceramic Capacitors (AREA)
Abstract
A multilayer capacitor comprises a multilayer body in which a plurality of dielectric layers and a plurality of first and second inner electrodes are alternately laminated, and first and second terminal electrodes formed on the multilayer body. The plurality of first and second inner electrodes are electrically connected to each other through a connecting conductor. A part of the plurality of first inner electrodes and a part of the plurality of second inner electrodes are electrically connected to the first and second terminal electrodes through lead conductors, respectively. Each first inner electrode connected to the respective first terminal electrode through the lead conductor and each second inner electrode connected to the respective terminal electrode through the lead conductor are arranged at positions symmetrical to each other about the center position in the laminating direction of the multilayer body. Alternatively, one or a plurality of first inner electrodes connected to the first terminal electrode through the lead conductor and one or a plurality of second inner electrodes connected to the second terminal electrode through the lead conductor are arranged at respective positions symmetrical to each other about the center position in the laminating direction of the multilayer body.
Description
Technical field
The present invention relates to stacked capacitor.
Background technology
As known the having of this stacked capacitor, the stacked capacitor (for example, with reference to patent documentation 1) of laminate that has possessed a plurality of dielectric layers and a plurality of internal electrodes alternately laminated and a plurality of termination electrodes that on this laminate, form.
Be used for to the supply power supply that is installed in central processing unit (CPU) supply power on the digital electronic device, load current increases in lower voltage.Therefore, be difficult to the variation of supply voltage is controlled in the permissible value with respect to the rapid variation of load current, so, the stacked capacitor that is called decoupling capacitor on power supply, connected gradually.So, when excessively change takes place load current, to the CPU supplying electric current, suppress the change of supply voltage by this stacked capacitor.
In recent years, along with the further high-frequencyization of the operating frequency of CPU, load current becomes bigger under high speed, in the stacked capacitor that uses in decoupling capacitor, requires to increase equivalent series resistance (ESR) in high capacity.
[patent documentation 1] Japanese kokai publication hei 9-148174 communique
But the stacked capacitor of record does not carry out in order to increase the research of equivalent series resistance in the patent documentation 1.And in the stacked capacitor of being put down in writing in patent documentation 1, whole internal electrodes directly is connected with termination electrode.Therefore, in this stacked capacitor, when increase increased static capacity corresponding to the stacked number of high capacity, equivalent series resistance can diminish.
Summary of the invention
The present invention makes in order to address the above problem, and its problem is that the stacked capacitor that can increase equivalent series resistance is provided.
In order to reach such purpose, the present inventor has carried out wholwe-hearted research to the stacked capacitor that may increase equivalent series resistance.Its result, the present inventor has found the following new fact: even be made as the stacked number of dielectric layer and internal electrode identical, if by bonding conductor connect internal electrode and only some internal electrode be connected with termination electrode by conductor introduction, also may increase equivalent series resistance.
But only a part of internal electrode is connected in the problem that exists in the stacked capacitor of termination electrode and is such: which face on the stacked direction with laminate in relative 2 sides is implemented to install with respect to substrate etc.That is, stacked capacitor is mounted for, and the land pattern (land pattern) that forms on termination electrode and the substrate is connected.In the stacked capacitor of on substrate, installing,, between side's land pattern and other land pattern, form current path by being connected in the internal electrode of termination electrode.When electric current flows through this current path, in stacked capacitor, produce inductance.The size of this inductance is according to the length of the current path that forms between land pattern and difference.The length of this current path is by the distance decision of internal electrode that is connected in termination electrode and land pattern.So, in general, be connected in the stacked capacitor of termination electrode at some internal electrode, according to which side and the substrate of laminate are relatively installed, can change the distance of the internal electrode and the land pattern that are connected in termination electrode, therefore, can change the length of current path according to installation direction.Its result, equivalent series inductance depends on the installation direction of stacked capacitor, can produce the problem of fluctuation.
So the present inventor has carried out wholwe-hearted research to the stacked capacitor that satisfies requirement that increases equivalent series resistance and the requirement of the fluctuation that suppresses equivalent series inductance simultaneously.Its as a result the present inventor found the following new fact: some internal electrode is connected with termination electrode by conductor introduction by being connected internal electrode by bonding conductor and only making, simultaneously, make the position symmetry in laminate that is connected in the internal electrode of termination electrode through conductor introduction, the fluctuation that can either suppress equivalent series inductance can increase equivalent series resistance again.Particularly, if can change the position of the number or the conductor introduction on the stacked direction of laminate of conductor introduction, just equivalent series resistance can be adjusted to desirable value.
According to such result of study, the stacked capacitor that the present invention is correlated be possessed a plurality of dielectric layers alternately laminated and the laminate of a plurality of internal electrodes and, the stacked capacitor of a plurality of termination electrodes of on laminate, forming, it is characterized in that a plurality of termination electrodes comprise the 1st and the 2nd termination electrode of mutual electric insulation; A plurality of internal electrodes comprise the a plurality of the 1st and the 2nd internal electrode of alternate configurations; A plurality of the 1st internal electrodes are electrically connected mutually through bonding conductor; A plurality of the 2nd internal electrodes are electrically connected mutually through bonding conductor; Among a plurality of the 1st internal electrodes, more than 1, than the sum of the 1st internal electrode lack 1 number following, the 1st internal electrode, be electrically connected on the 1st termination electrode through conductor introduction; Among a plurality of the 2nd internal electrodes, more than 1, than the sum of the 2nd internal electrode lack 1 number following, the 2nd internal electrode, be electrically connected on the 2nd termination electrode through conductor introduction; With respect to the center of the stacked direction of laminate, with each the polar-symmetric position of the 1st internal electrical that is electrically connected on the 1st termination electrode through conductor introduction on, have the 2nd internal electrode that is electrically connected on the 2nd termination electrode through conductor introduction; With respect to the center of the stacked direction of laminate, with each the polar-symmetric position of the 2nd internal electrical that is electrically connected on the 2nd termination electrode through conductor introduction on, have the 1st internal electrode that is electrically connected on the 1st termination electrode through conductor introduction.
In addition, the stacked capacitor that the present invention is correlated with, be comprised a plurality of dielectric layers alternately laminated and the laminate of a plurality of internal electrodes and, the stacked capacitor of a plurality of termination electrodes of on laminate, forming, it is characterized in that a plurality of termination electrodes comprise the 1st and the 2nd termination electrode of mutual electric insulation; A plurality of internal electrodes comprise the a plurality of the 1st and the 2nd internal electrode of alternate configurations; A plurality of the 1st internal electrodes are electrically connected mutually through bonding conductor; A plurality of the 2nd internal electrodes are electrically connected mutually through bonding conductor; Among a plurality of the 1st internal electrodes, more than 1, than the sum of the 1st internal electrode lack 1 number following, the 1st internal electrode, be electrically connected on the 1st termination electrode through conductor introduction; Among a plurality of the 2nd internal electrodes, more than 1, than the sum of the 2nd internal electrode lack 1 number following, the 2nd internal electrode, be electrically connected on the 2nd termination electrode through conductor introduction; With respect in the center of the stacked direction of laminate, with each the polar-symmetric position of the 1st internal electrical that is electrically connected on the 1st termination electrode through conductor introduction on, have the 1st internal electrode that is electrically connected on the 1st termination electrode through conductor introduction; With respect to the center on the stacked direction of laminate, with each the polar-symmetric position of the 2nd internal electrical that is electrically connected on the 2nd termination electrode through conductor introduction on, have the 2nd internal electrode that is electrically connected on the 2nd termination electrode through conductor introduction.
These stacked capacitors have the 1st and the 2nd internal electrode that is not directly connected in the 1st and the 2nd termination electrode.Bonding conductor by having such internal electrode and they being electrically connected mutually in these stacked capacitors, can increase equivalent series resistance.In addition, in these stacked capacitors, with respect to the center on the stacked direction of laminate,, there is the internal electrode that is electrically connected on termination electrode through conductor introduction distinguishing on the position of symmetry with the 1st and the 2nd internal electrode that is electrically connected on the 1st and the 2nd termination electrode through conductor introduction.Therefore, no matter make the situation of installing with respect to substrate etc. with respect to which face in 2 sides of the stacked direction of laminate, the length of the current path that forms through internal electrode between the land pattern on the substrate also is difficult to change.Therefore, in these stacked capacitors, the fluctuation of the equivalent series inductance that is caused by installation direction is suppressed.
Preferred a plurality of the 1st internal electrodes are electrically connected on bonding conductor through conductor introduction, and a plurality of the 2nd internal electrodes are electrically connected on bonding conductor through conductor introduction, and bonding conductor is formed on the surface of laminate.Perhaps, preferred bonding conductor is the via conductors that is provided with on the stacked direction of laminate in laminate.At this moment, the 1st and the 2nd internal electrode is electrically connected mutually.
In addition, preferably be formed with otch on the 1st and the 2nd internal electrode of at least a portion in the a plurality of the 1st and the 2nd internal electrode, otch be formed into into, in having formed the 1st and the 2nd internal electrode separately of this otch, electric current oppositely flows through mutually and clips this otch and relative zone.At this moment, result from electric current and the magnetic field that produces is cancelled, can reach the purpose that reduces equivalent series inductance.
In addition, preferred laminate is made roughly rectangular shape, the 1st termination electrode be formed in the side parallel with the stacked direction of laminate, on the side that length direction extends, the 2nd termination electrode be formed on the parallel side of the stacked direction of laminate in, length direction extend and the side relative with the side that forms the 1st termination electrode on.Thus, along from the direction of the 1st termination electrode to the 2nd termination electrode, the overlapping length of the 1st and the 2nd internal electrode shortens.Its result can reduce the magnetic field by the electric current generation of flowing through the 1st and the 2nd internal electrode, can reach the purpose that reduces equivalent series inductance.
In addition, preferably by adjust respectively through conductor introduction be electrically connected on the 1st termination electrode the 1st internal electrode number and, be electrically connected on the number of the 2nd internal electrode of the 2nd termination electrode through conductor introduction, equivalent series resistance is set to desirable value.
According to this cascade capacitor, since by adjust through conductor introduction be electrically connected on the 1st termination electrode the 1st internal electrode number and, be electrically connected at least one number among the number of the 2nd internal electrode of the 2nd termination electrode through conductor introduction, equivalent series resistance is set to desirable value, so, can be easily and precision carry out the control of equivalent series resistance well.
In addition, preferably by adjust respectively through conductor introduction be electrically connected on the stacked direction of the 1st internal electrode at laminate of the 1st termination electrode the position and, be electrically connected on the position on the stacked direction of the 2nd internal electrode at described laminate of the 2nd termination electrode through conductor introduction, equivalent series resistance is set to desirable value.
According to this cascade capacitor, since by adjust through conductor introduction be electrically connected on the stacked direction of the 1st internal electrode at laminate of the 1st termination electrode the position and, be electrically connected at least one position of the position on the stacked direction of the 2nd internal electrode at laminate of the 2nd termination electrode through conductor introduction, equivalent series resistance is set to desirable value, so, can be easily and precision carry out the control of equivalent series resistance well.
In addition, preferably by adjust respectively further the number that is electrically connected the bonding conductor between a plurality of the 1st internal electrodes and, be electrically connected the number of the bonding conductor between a plurality of the 2nd internal electrodes, equivalent series resistance is set to desirable value.At this moment, can precision carry out the control of equivalent series resistance more well.
In addition, be connected in parallel between preferred a plurality of the 1st internal electrodes; Be connected in parallel between a plurality of the 2nd internal electrodes.At this moment, also little even in the resistance value of each the 1st internal electrode or each the 2nd internal electrode, fluctuate to the influence of the equivalent series resistance of stacked capacitor integral body, can suppress the reduction of the control precision of equivalent series resistance.
Can provide the stacked capacitor that can increase equivalent series resistance according to the present invention.
The present invention will become apparent by following given detailed description and the accompanying drawing that only provides by way of example, and in addition, these can not be considered to be for qualification of the present invention.
The further scope of application of the present invention can be known acquisition from detailed description given below.But, it should be understood that, following specify with specific only be the most preferred embodiment of the present invention that provides by way of example for example, those skilled in the art obviously can specify various changes and the modification of making within the spirit and scope of the present invention according to this.
Description of drawings
Fig. 1 is the stereogram of the relevant stacked capacitor of the 1st execution mode.
Fig. 2 is the exploded perspective view of the laminate that contains in the relevant stacked capacitor of the 1st execution mode.
Fig. 3 is the figure that is used to illustrate the state that the relevant stacked capacitor of the 1st execution mode is installed on substrate.
Fig. 4 is the schematic diagram that expression is installed in the section structure of the relevant stacked capacitor of the 1st execution mode on the substrate.
Fig. 5 is the exploded perspective view of the laminate that contains in the relevant stacked capacitor of the 2nd execution mode.
Fig. 6 is the exploded perspective view of the laminate that contains in the relevant stacked capacitor of the 3rd execution mode.
Fig. 7 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 4th execution mode.
Fig. 8 is the exploded perspective view of the laminate that comprises in the variation of the relevant stacked capacitor of the 4th execution mode.
Fig. 9 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 5th execution mode.
Figure 10 is mounted in the schematic diagram of the section structure of the relevant stacked capacitor of the 5th execution mode on the substrate.
Figure 11 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 6th execution mode.
Figure 12 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 7th execution mode.
Figure 13 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 8th execution mode.
Figure 14 is the stereogram of the relevant stacked capacitor of the 9th execution mode.
Figure 15 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 9th execution mode.
Figure 16 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 10th execution mode.
Figure 17 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 11st execution mode.
Figure 18 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 12nd execution mode.
Figure 19 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 13rd execution mode.
Figure 20 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 14th execution mode.
Figure 21 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 15th execution mode.
Figure 22 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 16th execution mode.
Figure 23 is the stereogram of the variation of the relevant stacked capacitor of the 1st execution mode.
Figure 24 is the exploded perspective view of the laminate that comprises in the variation of the relevant stacked capacitor of the 1st execution mode.
Figure 25 is the exploded perspective view of the variation of the relevant stacked capacitor of the 5th execution mode.
Embodiment
Below, the preferred implementation that present invention will be described in detail with reference to the accompanying.And, in explanation, adopt same-sign for identical element or key element with identical function, the repetitive description thereof will be omitted.In addition, in explanation, use sometimes " on " and the term of D score, these are corresponding to the above-below direction of each figure.
(the 1st execution mode)
The structure of the stacked capacitor C1 that the 1st execution mode is relevant is described with reference to Fig. 1 and Fig. 2.Fig. 1 is the stereogram of the relevant stacked capacitor of the 1st execution mode.Fig. 2 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 1st execution mode.
Stacked capacitor C1, the 1st and the 2nd termination electrode 3,5 and the 1st and the 2nd bonding conductor 7,9 that as shown in Figure 1, comprise laminate 1, on this laminate 1, form.
The 1st termination electrode 3 is formed on, be parallel in the side of stacked direction described later of laminate 1, on the side 1a that length direction extends.The 2nd termination electrode 5 is formed on, be parallel in the side of stacked direction described later of laminate 1, length direction extend and the side 1b relative with the side 1a that forms the 1st termination electrode 3 on.The 1st termination electrode 3 and the 2nd termination electrode 5 mutual electric insulations.
The 1st bonding conductor 7, the mode with the side 1c side that is positioned at laminate 1 is formed on the surface of laminate 1.The 2nd bonding conductor 9, the mode with the side 1d side that is positioned at laminate 1 is formed on the surface of laminate 1.The 1st bonding conductor 7 and the 2nd bonding conductor 9 mutual electric insulations.
Each the 1st internal electrode 31~34 is shape in the form of a substantially rectangular.The 1st internal electrode 31~34 is formed on respectively, from laminate 1 the parallel side of stacked direction (below, abbreviate " stacked direction " as) of dielectric layer 11~18,22 rise on the position with predetermined distance.On each the 1st internal electrode 31~34, be formed with the conductor introduction 51~54 that stretches out in the mode on the side 1c that is drawn out to laminate 1.
The 1st internal electrode 31~34 is electrically connected on the 1st bonding conductor 7 through conductor introduction 51~54 respectively.Thus, the 1st internal electrode 31~34 becomes the state that is electrically connected mutually through the 1st bonding conductor 7.
On the 1st internal electrode 31, conductor introduction 37 is formed with the 1st internal electrode 31 and becomes one, and stretches out from the 1st internal electrode 31 in the mode in the face of the side 1a of laminate 1.The 1st internal electrode 31 is electrically connected on the 1st termination electrode 3 through conductor introduction 37.Because the 1st internal electrode 31~34 is electrically connected mutually through the 1st bonding conductor 7, so the 1st internal electrode 32~34 also becomes the state that is electrically connected on the 1st termination electrode 3 through bonding conductor 7, the 1st internal electrode 31~34 becomes the state that is connected in parallel.In addition, to clip dielectric layer 22 adjacent on stacked direction for the side 1e of the 1st internal electrode 31 and laminate 1.
Each the 2nd internal electrode 41~44 rectangular shaped.The 2nd internal electrode 41~44 is respectively formed at, and has on the position of predetermined distance from the side parallel with the stacked direction of laminate 1.On each the 2nd internal electrode 41~44, be formed with the conductor introduction 61~64 that stretches out in the mode on the side 1d that is drawn out to laminate 1.
The 2nd internal electrode 41~44 is electrically connected on the 2nd bonding conductor 9 through conductor introduction 61~64 respectively.Thus, the 2nd internal electrode 41~44 becomes the state that is electrically connected mutually through the 2nd bonding conductor 9.
On the 2nd internal electrode 44, conductor introduction 47 is formed with the 2nd internal electrode 44 and becomes one, and stretches out from the 2nd internal electrode 44 in the mode in the face of the side 1b of laminate 1.The 2nd internal electrode 44 is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.Because the 2nd internal electrode 41~44 is electrically connected mutually through the 2nd bonding conductor 9, so the 2nd internal electrode 41~43 also becomes the state that is electrically connected on the 2nd termination electrode 5 through the 2nd bonding conductor 9, the 2nd internal electrode 41~44 becomes the state that is connected in parallel.In addition, to clip dielectric layer 18 adjacent on stacked direction for the side 1f of the 2nd internal electrode 44 and laminate 1.
Like this, in laminate 1, with respect to the center M on stacked direction, with the position of the 1st internal electrode 31 symmetries that are electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.On the other hand, in laminate 1, with respect to the center M on stacked direction, with the position of the 2nd internal electrode 44 symmetries that are electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.
In stacked capacitor C1, the number that is directly connected in the 1st internal electrode 31 of the 1st termination electrode 3 through conductor introduction 37 is 1, is less than the sum (being 4 in the present embodiment) of the 1st internal electrode 31~34.In addition, making the number that is directly connected in the 2nd internal electrode 44 of the 2nd termination electrode 5 through conductor introduction 47 is 1, makes its sum that is less than the 2nd internal electrode 41~44 (being 4 in the present embodiment).In addition, if be conceived to the 1st termination electrode 3, then the resistance components of the 1st bonding conductor 7 becomes the state that is connected in series with respect to the 1st termination electrode 3.In addition, if be conceived to the 2nd termination electrode 5, then the resistance components of the 2nd bonding conductor 9 becomes the state that is connected in series with respect to the 2nd termination electrode 5.Thus, stacked capacitor C1 is connected in the existing stacked capacitor of corresponding termination electrode than whole internal electrodes through conductor introduction, and equivalent series resistance increases.In addition,, can prevent the rapid reduction of the impedance in resonance frequency, make broad in band become possibility by increasing equivalent series resistance.
Like this, according to present embodiment, since by adjust respectively through conductor introduction 37 be electrically connected on the 1st termination electrode 3 the 1st internal electrode 31 number and, be electrically connected on the number of the 2nd internal electrode 44 of the 2nd termination electrode 5 through conductor introduction 47, the equivalent series resistance of stacked capacitor C1 is set to desirable value, so, can be easily and precision carry out the control of equivalent series resistance well.
In addition, in the present embodiment, for being connected in parallel, the 2nd internal electrode 41~44 is each other for being connected in parallel each other for the 1st internal electrode 31~34.Thus, even the resistance value of each the 1st internal electrode 31~34 or each the 2nd internal electrode 41~44 fluctuates, to the influence of the equivalent series resistance of stacked capacitor C1 integral body also less, can suppress the reduction of the control precision of equivalent series resistance.
Fig. 3 is used to illustrate the figure that the state of stacked capacitor C1 is installed on substrate 110.Fig. 3 represents that the 1st termination electrode 3 is connected on the negative electrode land pattern 112 that forms on the substrate 110, the 2nd termination electrode 5 is connected to the state on anode land pattern 114.
Fig. 4 is the schematic diagram that is illustrated in the section structure of the cascade capacitor C1 that installs on the substrate 110.The state of in Fig. 4, representing that to be stacked capacitor C1 be mounted in the side 1f of laminate 1 and substrate 110 relative modes.In addition, Fig. 4 represents, in substrate 110, negative electrode land pattern 112 is connected in the state that distribution 116, anode land pattern 114 are connected in distribution 118.Be appreciated that from Fig. 4, formed among the stacked capacitor C1 that on substrate 110, installs, from negative electrode land pattern 112, through the 1st termination electrode 3, the 1st internal electrode 31 that is connected in the 1st termination electrode 3, the 2nd internal electrode 44 that is connected in the 2nd termination electrode 5 and the 2nd termination electrode 5, to the current path of anode land pattern 114.In addition, in Fig. 4, omitted the hatching that is equivalent to dielectric layer 11~18,22 and distribution 116,118 zones.
Electric current flows through when 112,114 current paths that form like this of land pattern, produces inductance.The size of this inductance is according to the length of current path and difference.In stacked capacitor C1, the internal electrode 31,44 that is connected in termination electrode 3,5 is configured in, with respect on the symmetrical mutually position of the center M on the stacked direction of laminate 1.Therefore, even so that the side 1e (rather than 1f) of laminate 1 installs stacked capacitor C1 with respect to the mode of substrate 110, be connected in the internal electrode 31,44 of termination electrode 3,5 and the distance on stacked direction of land pattern 112,114 and also be difficult to change.That is, in stacked capacitor C1, the variation that is caused by installation direction of the length of the current path that forms between land pattern is suppressed.Consequently, in stacked capacitor C1, the value of equivalent series inductance does not rely on the direction of installation, has suppressed the fluctuation of the equivalent series inductance that taken place by installation direction yet.
In addition, the 1st termination electrode 3 be formed in the side parallel with the stacked direction of the laminate 1 of rectangular shape, on the side 1a that length direction extends, the 2nd termination electrode 5 be formed on the parallel side of the stacked direction of laminate 1 in, on the relative side 1b of side 1a that length direction extends and forms with the 1st termination electrode 3.Thus, along from the direction of the 1st termination electrode 3 to the 2nd termination electrode 5, the overlap length of the 1st and the 2nd internal electrode 31~34,41~44 shortens.Consequently, magnetic field can be reduced, the purpose that equivalent series inductance reduces in stacked capacitor C 1 can be reached by the electric current generation of flowing through the 1st and the 2nd internal electrode 31~34,41~44.
(the 2nd execution mode)
The structure of the stacked capacitor that the 2nd execution mode is relevant is described with reference to Fig. 5.The difference of the stacked capacitor C1 that the stacked capacitor that the 2nd execution mode is relevant is relevant with the 1st execution mode is, through conductor introduction 37 be connected in the 1st termination electrode 3 the 1st internal electrode 33 and, be connected in the 2nd position of internal electrode 42 on stacked direction of the 2nd termination electrode 5 through conductor introduction 47.Fig. 5 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 2nd execution mode.
The stacked capacitor that the 2nd execution mode is relevant, omitted its diagram, but its stacked capacitor C1 relevant with the 1st execution mode is identical, the 1st termination electrode 3 that comprises laminate 1, on this laminate 1, forms, the 2nd termination electrode 5 that on identical laminate 1, forms and, the 1st and the 2nd bonding conductor 7,9.
In the relevant stacked capacitor of the 2nd execution mode, as shown in Figure 5, in 4 the 1st internal electrodes 31~34 from last the 3rd the 1st internal electrode 33, be electrically connected on the 1st termination electrode 3 through conductor introduction 37.Thus, the 1st internal electrode 31,32,34 also becomes the state that is electrically connected on the 1st termination electrode 3, and the 1st internal electrode 31~34 becomes the state that is connected in parallel.Conductor introduction 37 is formed with the 1st internal electrode 33 and becomes one, and in the mode in the face of side 1a in the side parallel with the stacked direction of laminate 1, that extend in the longitudinal direction, stretches out from the 1st internal electrode 33.
In the relevant stacked capacitor of the 2nd execution mode, as shown in Figure 5, in 4 the 2nd internal electrodes 41~44 from last the 2nd the 2nd internal electrode 42, be electrically connected on the 2nd termination electrode 5 through conductor introduction 47.Thus, the 2nd internal electrode 41,43,44 also becomes the state that is electrically connected on the 2nd termination electrode 5, and the 2nd internal electrode 41~44 becomes the state that is connected in parallel.Conductor introduction 47 is formed with the 2nd internal electrode 42 and becomes one, and with in the face of with the parallel side of the stacked direction of laminate 1 in, extend in the longitudinal direction and the mode of the side 1b relative with side 1a, stretch out from the 2nd internal electrode 42.
In the relevant stacked capacitor of the 2nd execution mode, making the number that is directly connected in the 1st internal electrode 33 of the 1st termination electrode 3 through conductor introduction 37 is 1, makes its sum that is less than the 1st internal electrode 31~34 (being 4 in the present embodiment).In addition, making the number that is directly connected in the 2nd internal electrode 42 of the 2nd termination electrode 5 through conductor introduction 47 is 1, makes its sum that is less than the 2nd internal electrode 41~44 (being 4 in the present embodiment).Thus, the stacked capacitor that the 2nd execution mode is relevant is connected in the existing stacked capacitor of corresponding termination electrode than whole internal electrodes through conductor introduction, and equivalent series resistance increases.
In addition, if be conceived to the 1st termination electrode 3, then the resistance components of the 1st bonding conductor 7 is that boundary is divided into the 1st internal electrode 33, more be positioned at than the 1st internal electrode 33 stacked direction a side the 1st bonding conductor 7 resistance components and more be positioned at the resistance components of the 1st bonding conductor 7 of the opposite side of stacked direction than the 1st internal electrode 33.These resistance components become the state that is connected in parallel with respect to the 1st termination electrode 3.In addition, if be conceived to the 2nd termination electrode 5, then the resistance components of the 2nd bonding conductor 9 is that boundary is divided into the 2nd internal electrode 42, more be positioned at than the 2nd internal electrode 42 stacked direction a side the 2nd bonding conductor 9 resistance components and more be positioned at the resistance components of the 2nd bonding conductor 9 of the opposite side of stacked direction than the 2nd internal electrode 42.These resistance components become the state that is connected in parallel with respect to the 2nd termination electrode 5.
Therefore, since the difference of the resistance components of the 1st and the 2nd bonding conductor 7,9, the cascade capacitor that the 2nd execution mode is relevant, and than the relevant cascade capacitor C1 of the 1st execution mode, equivalent series resistance diminishes.
As mentioned above, according to present embodiment, since by adjust respectively be electrically connected on the 1st termination electrode 3 through conductor introduction 37 the 1st internal electrode 33 in the position on the stacked direction and, be electrically connected on the 2nd position of internal electrode 42 on stacked direction of the 2nd termination electrode 5 through conductor introduction 47, the equivalent series resistance of stacked capacitor C1 is set to desirable value, so, can be easily and precision carry out the control of equivalent series resistance well.
In addition, in the laminate 1 of the stacked capacitor that the 2nd execution mode is relevant, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 33 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 2nd internal electrode 42 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.On the other hand, in the laminate 1 of the relevant stacked capacitor of the 2nd execution mode, with respect to the center M on stacked direction, with the symmetrical position of the 2nd internal electrode 42 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 1st internal electrode 33 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.Therefore, no matter will implement to install with respect to substrate etc. with respect to which face among 2 side 1e, the 1f of the stacked direction of laminate 1, the length of the current path that forms through internal electrode in waiting between the land pattern on substrate all be difficult to change.Therefore, in the relevant stacked capacitor of the 2nd execution mode, suppressed the fluctuation of the equivalent series inductance that causes by installation direction.
In addition, the 1st termination electrode 3 be formed in the side parallel with the stacked direction of the laminate 1 of rectangular shape, on the side 1a that length direction extends, the 2nd termination electrode 5 be formed on the parallel side of the stacked direction of laminate 1 in, on the relative side 1b of side 1a that length direction extends and forms with the 1st termination electrode 3.Thus, magnetic field can be reduced, the purpose that in the relevant stacked capacitor of the 2nd execution mode, reduces equivalent series inductance can be reached by the electric current generation of flowing through the 1st and the 2nd internal electrode 31~34,41~44.
(the 3rd execution mode)
The structure of the stacked capacitor that the 3rd execution mode is relevant is described with reference to Fig. 6.The difference of the stacked capacitor C1 that the stacked capacitor that the 3rd execution mode is relevant is relevant with the 1st execution mode is, is connected in the number of the 1st and the 2nd internal electrode 31,34,41,44 of termination electrode 3,5 through conductor introduction 37,47.Fig. 6 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 3rd execution mode.
The stacked capacitor that the 3rd execution mode is relevant, omit its diagram, but the 1st termination electrode 3 that its stacked capacitor C1 relevant with the 1st execution mode is same, comprises laminate 1, form on this laminate 1, the 2nd termination electrode 5 that on identical laminate 1, forms and, the 1st and the 2nd bonding conductor 7,9.
In the relevant stacked capacitor of the 3rd execution mode, as shown in Figure 6,2 the 1st internal electrodes 31,34 in 4 the 1st internal electrodes 31~34 are electrically connected on the 1st termination electrode 3 through conductor introduction 37.Because the 1st internal electrode 31~34 is electrically connected mutually through the 1st bonding conductor 7, so the 1st internal electrode 32,33 also becomes the state that is electrically connected on the 1st termination electrode 3 through the 1st bonding conductor 7, the 1st internal electrode 31~34 becomes the state that is connected in parallel.Conductor introduction 37 is formed with each the 1st internal electrode 31,34 and becomes one, and in the mode in the face of side 1a in the side parallel with the stacked direction of laminate 1, that extend in the longitudinal direction, stretches out respectively from the 1st internal electrode 31,34.
2 the 2nd internal electrodes 41,44 in 4 the 2nd internal electrodes 41~44 are electrically connected on the 2nd termination electrode 5 through conductor introduction 47.Because the 2nd internal electrode 41~44 is electrically connected mutually through the 2nd bonding conductor 9, so the 2nd internal electrode 42,43 also becomes the state that is electrically connected on the 2nd termination electrode 5 through the 2nd bonding conductor 9, the 2nd internal electrode 41~44 becomes the state that is connected in parallel.Conductor introduction 47 is formed with each the 2nd internal electrode 41,44 and becomes one, and with in the face of with the parallel side of the stacked direction of laminate 1 in, extend in the longitudinal direction and the mode of the side 1b relative with side 1a, stretch out respectively from the 2nd internal electrode 41,44.
In the relevant stacked capacitor of the 3rd execution mode, making the number that is directly connected in the 1st internal electrode 31,34 of the 1st termination electrode 3 through conductor introduction 37 is 2, makes it be less than the sum of the 1st internal electrode 31~34.In addition, making the number that is directly connected in the 2nd internal electrode 41,44 of the 2nd termination electrode 5 through conductor introduction 47 is 2, makes it be less than the sum of the 2nd internal electrode 41~44.Therefore, the stacked capacitor that the 3rd execution mode is relevant is compared through the existing stacked capacitor that conductor introduction is connected in corresponding termination electrode with whole internal electrodes, and equivalent series resistance increases.
The relevant stacked capacitor of the 3rd execution mode is than stacked capacitor C1, and the number of the 1st internal electrode 31,34 that is directly connected in the 1st termination electrode 3 through conductor introduction 37 is more, and these conductor introductions 37 are connected in parallel with respect to the 1st termination electrode 3.In addition, the number of the 2nd internal electrode 41,44 that is directly connected in the 2nd termination electrode 5 through conductor introduction 47 is more, and these conductor introductions 47 are connected in parallel with respect to the 2nd termination electrode 5.Therefore, the equivalent series resistance of the stacked capacitor that the 3rd execution mode is relevant diminishes than the equivalent series resistance of stacked capacitor C1.
As mentioned above, according to present embodiment, since by adjust respectively through conductor introduction 37 be electrically connected on the 1st termination electrode 3 the 1st internal electrode 31,34 number and, be electrically connected on the number of the 2nd internal electrode 41,44 of the 2nd termination electrode 5 through conductor introduction 47, the equivalent series resistance of the stacked capacitor that the 3rd execution mode is relevant is set to desirable value, so, can be easily and precision carry out the control of equivalent series resistance well.
In addition, in the laminate 1 of the stacked capacitor that the 3rd execution mode is relevant, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 34 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 2nd internal electrode 41 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.On the other hand, in the laminate 1 of the relevant stacked capacitor of the 3rd execution mode, with respect to the center M on stacked direction, with the symmetrical position of the 2nd internal electrode 41 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 1st internal electrode 34 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.Therefore, situation about will install with respect to substrate etc. with respect to which face among 2 side 1e, the 1f of the stacked direction of laminate 1 no matter, the length of the current path that forms through internal electrode in waiting between the land pattern on the substrate all is difficult to change.Therefore, in the relevant stacked capacitor of the 3rd execution mode, suppressed the fluctuation of the equivalent series inductance that causes by installation direction.
In addition, the 1st termination electrode 3 be formed in the side parallel with the stacked direction of the laminate 1 of rectangular shape, on the side 1a that length direction extends, the 2nd termination electrode 5 be formed on the parallel side of the stacked direction of laminate 1 in, on the relative side 1b of side 1a that length direction extends and forms with the 1st termination electrode 3.Thus, magnetic field can be reduced, the purpose that in the relevant stacked capacitor of the 3rd execution mode, reduces equivalent series inductance can be reached by the electric current generation of flowing through the 1st and the 2nd internal electrode 31~34,41~44.
(the 4th execution mode)
The structure of the stacked capacitor that the 4th execution mode is relevant is described with reference to Fig. 7.The difference of the stacked capacitor C1 that the stacked capacitor that the 4th execution mode is relevant is relevant with the 1st execution mode is, is formed with otch on the 1st and the 2nd internal electrode 32~34,41~43.Fig. 7 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 4th execution mode.
The stacked capacitor that the 4th execution mode is relevant, omit its diagram, but the 1st termination electrode 3 that its stacked capacitor C1 relevant with the 1st execution mode is same, comprises laminate 1, form on this laminate 1, the 2nd termination electrode 5 that on identical laminate 1, forms and, the 1st and the 2nd bonding conductor 7,9.
In the 1st internal electrode 32~34,, form otch S11~S13 with from the next door of the coupling part of conductor introduction 52~54 and the 1st internal electrode 32~34, to the mode that the length direction of the 1st internal electrode 32~34 extends.Therefore, otch S11~S13 be formed into into, in each the 1st internal electrode 32~34, electric current oppositely flows through mutually and clips otch S11~S13 respectively and relative zone.
In the 2nd internal electrode 41~43,, form otch S21~S23 with from the next door of the coupling part of conductor introduction 61~63 and the 2nd internal electrode 41~43, to the mode that the length direction of the 2nd internal electrode 41~43 extends.Therefore, otch S21~S23 be formed into into, in each the 2nd internal electrode 41~43, electric current oppositely flows through mutually and clips otch S21~S23 respectively and relative zone.
In having formed the 1st and the 2nd internal electrode 32~34,41~43 of otch S11~S13, S21~S23, owing to electric current in the zone relative clipping otch S11~S13, S21~S23 respectively oppositely flows through mutually, so, result from electric current and cancelled each other in the magnetic field that produces.And in the 1st internal electrode 32~34 that has formed otch and the 2nd internal electrode 41~43, from stacked direction, the direction that flows through of electric current is oppositely.Therefore, result from the magnetic field flowing through the electric current of the 1st internal electrode 32~34 and produce with result from the magnetic field of flowing through the electric current of the 2nd internal electrode 41~43 and producing and cancelled each other.Therefore, in the relevant stacked capacitor of the 4th execution mode, can reach the purpose that reduces equivalent series inductance.
In addition, in the relevant stacked capacitor of the 4th execution mode, making the number that is directly connected in the 1st internal electrode 31 of the 1st termination electrode 3 through conductor introduction 37 is 1, makes its sum that is less than the 1st internal electrode 31~34 (being 4 in the present embodiment).In addition, making the number that is directly connected in the 2nd internal electrode 44 of the 2nd termination electrode 5 through conductor introduction 47 is 1, makes its sum that is less than the 2nd internal electrode 41~44 (being 4 in the present embodiment).Thus, the stacked capacitor that the 4th execution mode is relevant is connected in the existing stacked capacitor of corresponding termination electrode than whole internal electrodes through conductor introduction, and equivalent series resistance increases.
As mentioned above, according to present embodiment, since by adjust respectively through conductor introduction 37 be electrically connected on the 1st termination electrode 3 the 1st internal electrode 31 number and, be electrically connected on the number of the 2nd internal electrode 44 of the 2nd termination electrode 5 through conductor introduction 47, the equivalent series resistance of the stacked capacitor that the 4th execution mode is relevant is set to desirable value, so, can be easily and precision carry out the control of equivalent series resistance well.
In addition, in the laminate 1 of the stacked capacitor that the 4th execution mode is relevant, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.On the other hand, in the laminate 1 of the relevant stacked capacitor of the 4th execution mode, with respect to center M at the stacked direction of laminate, with the symmetrical position of the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.Therefore, situation about will install with respect to substrate etc. with respect to which face among 2 side 1e, the 1f of the stacked direction of laminate 1 no matter, the length of the current path that forms through internal electrode in waiting between the land pattern on the substrate all is difficult to change.Therefore, in the relevant stacked capacitor of the 4th execution mode, suppressed the fluctuation of the equivalent series inductance that causes by installation direction.
In addition, the 1st termination electrode 3 be formed in the side parallel with the stacked direction of the laminate 1 of rectangular shape, on the side 1a that length direction extends, the 2nd termination electrode 5 be formed on the parallel side of the stacked direction of laminate 1 in, length direction extend and the side 1b relative with the side 1a that is formed with the 1st termination electrode 3 on.Thus, magnetic field can be reduced, the purpose that in the relevant stacked capacitor of the 4th execution mode, reduces equivalent series inductance can be reached by the electric current generation of flowing through the 1st and the 2nd internal electrode 31~34,41~44.
In addition, the internal electrode of formation otch is not limited to the 1st and the 2nd internal electrode 32~34,41~43.Promptly, otch also can be formed on the 1st and the 2nd internal electrode 32~34,41~43 internal electrode in addition, for example, also can be formed on by conductor introduction 37,47 and be electrically connected on the 1st and the 2nd internal electrode 31,44 of the 1st and the 2nd termination electrode 3,5.As the example of this situation, in Fig. 8, represented on the 1st and the 2nd internal electrode 31~36,41~45, to have formed the exploded perspective view of the stacked capacitor of otch S11~S14, S21~S24.By on the 1st and the 2nd internal electrode 31,44 that is electrically connected on the 1st and the 2nd termination electrode 3,5 through conductor introduction 37,47, forming otch S11, S24, in these internal electrodes 31,44, result from electric current and cancelled out each other in the magnetic field that produces.Therefore, can reach the purpose that in stacked capacitor, further reduces equivalent series inductance.
(the 5th execution mode)
The structure of the stacked capacitor that the 5th execution mode is relevant is described with reference to Fig. 9.The difference of the stacked capacitor C1 that the stacked capacitor that the 5th execution mode is relevant is relevant with the 1st execution mode is: the 1st internal electrode is, the internal electrode that exists on respect to symmetrical position, the center on the stacked direction at laminate at the 1st internal electrode that is connected with the 1st termination electrode; The 2nd internal electrode is, the internal electrode that exists on respect to symmetrical position, the center on the stacked direction at laminate at the 2nd internal electrode that is connected with the 2nd termination electrode.Fig. 9 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 5th execution mode.
The stacked capacitor that the 5th execution mode is relevant, omit its diagram, but the 1st termination electrode 3 that its stacked capacitor C1 relevant with the 1st execution mode is same, comprises laminate 1, form on this laminate 1, the 2nd termination electrode 5 that on identical laminate 1, forms and, the 1st and the 2nd bonding conductor 7,9.
Each the 1st internal electrode 31~36 is shape in the form of a substantially rectangular.The 1st internal electrode 31~36 is respectively formed at, from laminate 1 dielectric layer 11~22 stacked direction (below, abbreviate " stacked direction " as.) parallel side rises, has on the position of predetermined distance.On each the 1st internal electrode 31~36, be formed with the conductor introduction 51~56 that stretches out in the mode on the side 1c that is drawn out to laminate 1.
The 1st internal electrode 31~36 is electrically connected on the 1st bonding conductor 7 through conductor introduction 51~56 respectively.Thus, the 1st internal electrode 31~36 becomes the state that is electrically connected mutually through the 1st bonding conductor 7.
On the 1st internal electrode 31, conductor introduction 37 is formed with the 1st internal electrode 31 and becomes one, and stretches out from the 1st internal electrode 31 in the mode in the face of the side 1a of laminate 1.The 1st internal electrode 31 is electrically connected on the 1st termination electrode 3 through conductor introduction 37.On the 1st internal electrode 36, conductor introduction 37 is formed with the 1st internal electrode 36 and becomes one, and stretches out from the 1st internal electrode 36 in the mode in the face of the side 1a of laminate 1.The 1st internal electrode 36 is electrically connected on the 1st termination electrode 3 through conductor introduction 37.Because the 1st internal electrode 31~36 is electrically connected mutually through the 1st bonding conductor 7, so the 1st internal electrode 32~35 also becomes the state that is electrically connected on the 1st termination electrode 3 through the 1st bonding conductor 7, the 1st internal electrode 31~36 becomes the state that is connected in parallel.In addition, the 1st internal electrode 31 is adjacent on stacked direction through dielectric layer 22 with the side 1e of laminate 1.The 1st internal electrode 36 is adjacent on stacked direction through dielectric layer 21 with the side 1f of laminate 1.
Each the 2nd internal electrode 41~45 is shape in the form of a substantially rectangular.The 2nd internal electrode 41~45 is respectively formed at, and has on the position of predetermined distance from the side parallel with the stacked direction the laminate 1.On each the 2nd internal electrode 41~45, be formed with the conductor introduction 61~65 that stretches out in the mode on the side 1d that is drawn out to laminate 1.
The 2nd internal electrode 41~45 is electrically connected on the 2nd bonding conductor 9 through conductor introduction 61~65 respectively.Thus, the 2nd internal electrode 41~45 becomes the state that is electrically connected mutually through the 2nd bonding conductor 9.
On the 2nd internal electrode 41, conductor introduction 47 is formed with the 2nd internal electrode 41 and becomes one, and stretches out from the 2nd internal electrode 41 in the mode in the face of the side 1b of laminate 1.The 2nd internal electrode 41 is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.On the 2nd internal electrode 45, conductor introduction 47 is formed with the 2nd internal electrode 45 and becomes one, and stretches out from the 2nd internal electrode 45 in the mode in the face of the side 1b of laminate 1.The 2nd internal electrode 45 is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.Because the 2nd internal electrode 41~45 is electrically connected mutually through the 2nd bonding conductor 9, so the 2nd internal electrode 42~44 also becomes the state that is electrically connected on the 2nd termination electrode 5 through the 2nd bonding conductor 9, the 2nd internal electrode 41~45 becomes the state that is connected in parallel.
Like this, in laminate 1, with respect to the center M on the stacked direction, with the symmetrical position of the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 36 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 36 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.
On the other hand, in laminate 1, with respect to the center M on the stacked direction, with the symmetrical position of the 2nd internal electrode 41 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 45 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.In laminate 1, with respect to the center M on the stacked direction, with the symmetrical position of the 2nd internal electrode 45 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 41 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.
In the relevant stacked capacitor of the 5th execution mode, making the number that is directly connected in the 1st internal electrode 31,36 of the 1st termination electrode 3 through conductor introduction 37 is 2, makes its sum that is less than the 1st internal electrode 31~36 (being 6 in the present embodiment).In addition, making the number that is directly connected in the 2nd internal electrode 41,45 of the 2nd termination electrode 5 through conductor introduction 47 is 2, makes its sum that is less than the 2nd internal electrode 41~45 (being 5 in the present embodiment).Therefore, the stacked capacitor that the 5th execution mode is relevant is connected in the existing stacked capacitor of corresponding termination electrode than whole internal electrodes through conductor introduction, and equivalent series resistance increases.In addition,, can prevent the rapid reduction of the impedance in resonance frequency, make broad in band become possibility by increasing equivalent series resistance.
Like this, according to present embodiment, since by adjust respectively through conductor introduction 37 be electrically connected on the 1st termination electrode 3 the 1st internal electrode 31,36 number and, be electrically connected on the number of the 2nd internal electrode 41,45 of the 2nd termination electrode 5 through conductor introduction 47, the equivalent series resistance of the stacked capacitor that the 5th execution mode is relevant is set to desirable value, so, can be easily and precision carry out the control of equivalent series resistance well.
In addition, in the present embodiment, for being connected in parallel, the 2nd internal electrode 41~45 is each other for being connected in parallel each other for the 1st internal electrode 31~36.Thus, even in the resistance value of each the 1st internal electrode 31~36 or each the 2nd internal electrode 41~45, fluctuate, influence to the equivalent series resistance in the relevant stacked capacitor integral body of the 5th execution mode is also few, can suppress the reduction of the control precision of equivalent series resistance.
In addition, Figure 10 is the schematic diagram that is illustrated on the substrate 110 section structure of the relevant cascade capacitor of the 5th execution mode installed.What represent in Figure 10 is, the state that the relevant stacked capacitor of the 5th execution mode is mounted in the side 1f of laminate 1 and substrate 110 relative modes.In addition, what Figure 10 represented is, in substrate 110, negative electrode land pattern 112 is connected in distribution 116, and anode land pattern 114 is connected in the state of distribution 118.Be appreciated that from Figure 10, formed in the stacked capacitor that the 5th execution mode of installing on substrate 110 is correlated with, from negative electrode land pattern 112, through the 1st termination electrode 3, be connected in the 1st termination electrode 3 the 1st internal electrode 31,36, be connected in the 2nd internal electrode 41,45 and the 2nd termination electrode 5 of the 2nd termination electrode 5, to the current path of anode land pattern 114.In addition, in Figure 10, omitted the hatching that is equivalent to dielectric layer 11~22 and distribution 116,118 zones.
When flowing through the current path that forms like this between land pattern, electric current produces inductance.The size of this inductance is according to the length of current path and difference.In the relevant stacked capacitor of the 5th execution mode, with respect to each internal electrode 31,36,41,45 that is connected in termination electrode 3,5, with respect on the position of the center M on the stacked direction of laminate 1, mutual symmetry, there is internal electrode 36,31,45,41 respectively.Therefore, even with respect to the mode of substrate 110 the relevant stacked capacitor of the 5th execution mode is installed, is connected in the internal electrode 31,36,41,45 of termination electrode 3,5 and the distance on stacked direction of land pattern 112,114 and also is difficult to change with side 1e (rather than 1f) with laminate 1.That is, in the relevant stacked capacitor of the 5th execution mode, the variation that is caused by installation direction of the length of the current path that forms between land pattern is suppressed.Consequently, in the relevant stacked capacitor of the 5th execution mode, the value of equivalent series inductance does not rely on the direction of installation, has suppressed the fluctuation of the equivalent series inductance that taken place by installation direction yet.
In addition, the 1st termination electrode 3 is formed on, in the side parallel with the stacked direction of the laminate 1 of rectangular shape, on the side 1a that length direction extends, the 2nd termination electrode 5 is formed on, with in the parallel side of the stacked direction of laminate 1, extend in the longitudinal direction and the side 1b relative with the side 1a that forms the 1st termination electrode 3 on.Thus, along from the direction of the 1st termination electrode 3 to the 2nd termination electrode 5, the overlap length of the 1st and the 2nd internal electrode 31~36,41~45 shortens.Consequently, magnetic field can be reduced, the purpose that in the relevant stacked capacitor of the 5th execution mode, reduces equivalent series inductance can be reached by the electric current generation of flowing through the 1st and the 2nd internal electrode 31~36,41~45.
(the 6th execution mode)
The structure of the stacked capacitor that the 6th execution mode is relevant is described with reference to Figure 11.The difference of the stacked capacitor that the stacked capacitor that the 6th execution mode is relevant is relevant with the 5th execution mode is, through conductor introduction 37 be connected in the 1st termination electrode 3 the 1st internal electrode 33,34 and, be connected in the position on stacked direction of the 2nd internal electrode 42,44 of the 2nd termination electrode 5 through conductor introduction 47.Figure 11 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 6th execution mode.
The stacked capacitor that the 6th execution mode is relevant, omit its diagram, but the 1st termination electrode 3 that its stacked capacitor C1 relevant with the 1st execution mode is same, comprises laminate 1, form on this laminate 1, the 2nd termination electrode 5 that on identical laminate 1, forms and, the 1st and the 2nd bonding conductor 7,9.
In the relevant stacked capacitor of the 6th execution mode, as shown in figure 11, in 6 the 1st internal electrodes 31~36 from last the 3rd the 1st internal electrode 33 and, from last the 4th the 1st internal electrode 34, be electrically connected on the 1st termination electrode 3 through conductor introduction 37.Thus, the 1st internal electrode 31,32,35,36 also becomes the state that is electrically connected on the 1st termination electrode 3, and the 1st internal electrode 31~36 becomes the state that is connected in parallel.Conductor introduction 37 is formed with the 1st internal electrode 33,34 and becomes one, and in the mode in the face of side 1a in the side parallel with the stacked direction of laminate 1, that extend in the longitudinal direction, stretches out from the 1st internal electrode 33,34.
In the relevant stacked capacitor of the 6th execution mode, as shown in figure 11, in 5 the 2nd internal electrodes 41~45 from last the 2nd the 2nd internal electrode 42 and, from last the 4th the 2nd internal electrode 44, be electrically connected on the 2nd termination electrode 5 through conductor introduction 47.Thus, the 2nd internal electrode 41,43,45 also becomes the state that is electrically connected on the 2nd termination electrode 5, and the 2nd internal electrode 41~45 becomes the state that is connected in parallel.Conductor introduction 47 is formed with the 2nd internal electrode 42,44 and becomes one, and with in the face of with the parallel side of the stacked direction of laminate 1 in, extend in the longitudinal direction and the mode of the side 1b relative with side 1a, stretch out from the 2nd internal electrode 42,44.
In the relevant stacked capacitor of the 6th execution mode, making the number that is directly connected in the 1st internal electrode 33,34 of the 1st termination electrode 3 through conductor introduction 37 is 2, makes its sum that is less than the 1st internal electrode 31~36 (being 6 in the present embodiment).In addition, making the number that is directly connected in the 2nd internal electrode 42,44 of the 2nd termination electrode 5 through conductor introduction 47 is 2, makes its sum that is less than the 2nd internal electrode 41~45 (being 5 in the present embodiment).Thus, the stacked capacitor that the 6th execution mode is relevant is connected in the existing stacked capacitor of corresponding termination electrode than whole internal electrodes through conductor introduction, and equivalent series resistance increases.
In addition, if be conceived to the 1st termination electrode 3, then the stacked capacitor that the 6th execution mode is relevant is that than the difference of the relevant stacked capacitor of the 5th execution mode the resistance components of the 1st bonding conductor 7 is to the method for attachment of the 1st termination electrode 3.That is, in the relevant stacked capacitor of the 5th execution mode, the resistance components of the 1st bonding conductor 7 is connected in series with respect to the 1st internal electrode 31,36 respectively.And in the relevant stacked capacitor of the 6th execution mode, the resistance components of the 1st bonding conductor 7 is that boundary is separated with the 1st internal electrode 33,34 respectively, and these resistance components are connected in parallel with respect to the 1st termination electrode 3.In addition, if be conceived to the 2nd termination electrode 5, then the stacked capacitor that the 6th execution mode is relevant is that than the difference of the relevant stacked capacitor of the 5th execution mode the resistance components of the 2nd bonding conductor 9 is to the method for attachment of the 2nd termination electrode 5.That is, in the relevant stacked capacitor of the 5th execution mode, the resistance components of the 2nd bonding conductor 9 is connected in series with respect to the 2nd internal electrode 41,45 respectively.On the other hand, in the relevant stacked capacitor of the 6th execution mode, the resistance components of the 2nd bonding conductor 9 is that boundary is separated with the 2nd internal electrode 42,44 respectively, and these resistance components are connected in parallel with respect to the 2nd termination electrode 5.
Therefore, since the difference of the resistance components of the 1st and the 2nd bonding conductor 7,9, the cascade capacitor that the cascade capacitor that the 6th execution mode is relevant is correlated with than the 5th execution mode, and equivalent series resistance diminishes.
As mentioned above, according to present embodiment, since by adjust respectively through conductor introduction 37 be electrically connected on the 1st termination electrode 3 the 1st internal electrode 33,34 in the position on the stacked direction and, be electrically connected on the position on stacked direction of the 2nd internal electrode 42,44 of the 2nd termination electrode 5 through conductor introduction 47, the equivalent series resistance of stacked capacitor is set to desirable value, so, can be easily and precision carry out the control of equivalent series resistance well.
In addition, in the laminate 1 of the stacked capacitor that the 6th execution mode is relevant, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 33 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 34 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 34 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 33 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.And in the laminate 1 of the relevant stacked capacitor of the 6th execution mode, center M with respect to stacked direction, with the symmetrical position of the 2nd internal electrode 42 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.In laminate 1, with respect to the center M of stacked direction, with the symmetrical position of the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 42 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.Therefore, situation about will install with respect to substrate etc. with respect to which face among 2 side 1e, the 1f of the stacked direction of laminate 1 no matter, the length of the current path that forms through internal electrode in waiting between the land pattern on the substrate all is difficult to change.Therefore, in the relevant stacked capacitor of the 6th execution mode, the fluctuation of the equivalent series inductance that is caused by installation direction is suppressed.
In addition, the 1st termination electrode 3 be formed in the side parallel with the stacked direction of the laminate 1 of rectangular shape, on the side 1a that length direction extends, the 2nd termination electrode 5 be formed on the parallel side of the stacked direction of laminate 1 in, length direction extend and the side 1b relative with the side 1a that forms the 1st termination electrode 3 on.Thus, magnetic field can be reduced, the purpose that in the relevant stacked capacitor of the 6th execution mode, reduces equivalent series inductance can be reached by the electric current generation of flowing through the 1st and the 2nd internal electrode 31~36,41~45.
(the 7th execution mode)
The structure of the stacked capacitor that the 7th execution mode is relevant is described with reference to Figure 12.The difference of the stacked capacitor that the stacked capacitor that the 7th execution mode is relevant is relevant with the 5th execution mode is, is connected in the number of the 1st and the 2nd internal electrode 31,32,35,36,41,42,44,45 of termination electrode 3,5 through conductor introduction 37,47.Figure 12 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 7th execution mode.
The stacked capacitor that the 7th execution mode is relevant, omit its diagram, but the 1st termination electrode 3 that its stacked capacitor C1 relevant with the 1st execution mode is same, comprises laminate 1, form on this laminate 1 and, the 2nd termination electrode the 5, the 1st and the 2nd bonding conductor 7,9 that on identical laminate 1, form.
In the relevant stacked capacitor of the 7th execution mode, as shown in figure 12,4 the 1st internal electrodes 31,32,35,36 in 6 the 1st internal electrodes 31~36 are electrically connected on the 1st termination electrode 3 through conductor introduction 37.Because the 1st internal electrode 31~36 is electrically connected mutually through the 1st bonding conductor 7, so the 1st internal electrode 33,34 also becomes the state that is electrically connected on the 1st termination electrode 3 through the 1st bonding conductor 7, the 1st internal electrode 31~36 becomes the state that is connected in parallel.Conductor introduction 37 is formed with each the 1st internal electrode 31,32,35,36 and becomes one, and, stretch out from the 1st internal electrode 31,32,35,36 respectively in mode in the face of side 1a in the side parallel, that extend in the longitudinal direction with the stacked direction of laminate 1.
4 the 2nd internal electrodes 41,42,44,45 in 5 the 2nd internal electrodes 41~45 are electrically connected on the 2nd termination electrode 5 through conductor introduction 47.Because the 2nd internal electrode 41~45 is electrically connected mutually through the 2nd bonding conductor 9, so the 2nd internal electrode 43 also becomes the state that is electrically connected on the 2nd termination electrode 5 through the 2nd bonding conductor 9, the 2nd internal electrode 41~45 becomes the state that is connected in parallel.Conductor introduction 47 is formed with each the 2nd internal electrode 41,42,44,45 and becomes one, and with in the face of with the parallel side of the stacked direction of laminate 1 in, extend in the longitudinal direction and the mode of the side 1b relative with side 1a, stretch out from the 2nd internal electrode 41,42,44,45.
In the relevant stacked capacitor of the 7th execution mode, making the number that is directly connected in the 1st internal electrode 31,32,35,36 of the 1st termination electrode 3 through conductor introduction 37 is 4, makes it be less than the sum of the 1st internal electrode 31~36.In addition, making the number that is directly connected in the 2nd internal electrode 41,42,44,45 of the 2nd termination electrode 5 through conductor introduction 47 is 4, makes it be less than the sum of the 2nd internal electrode 41~45.Thus, the stacked capacitor that the 7th execution mode is relevant is compared through the existing stacked capacitor that conductor introduction is connected in corresponding termination electrode with whole internal electrodes, and equivalent series resistance increases.
The stacked capacitor that the stacked capacitor that the 7th execution mode is relevant is correlated with than the 5th execution mode, the number of the 1st internal electrode 31,32,35,36 that is directly connected in the 1st termination electrode 3 through conductor introduction 37 is more, and these conductor introduction 37 is connected in parallel with respect to the 1st termination electrode 3.In addition, the number of the 2nd internal electrode 41,42,44,45 that is directly connected in the 2nd termination electrode 5 through conductor introduction 47 is more, and these conductor introduction 47 is connected in parallel with respect to the 2nd termination electrode 5.Therefore, the equivalent series resistance of the stacked capacitor that the 7th execution mode is relevant is less than the equivalent series resistance of the relevant stacked capacitor of the 5th execution mode.
As mentioned above, according to present embodiment, since by adjust respectively through conductor introduction 37 be electrically connected on the 1st termination electrode 3 the 1st internal electrode 31,32,35,36 number and, be electrically connected on the number of the 2nd internal electrode 41,42,44,45 of the 2nd termination electrode 5 through conductor introduction 47, the equivalent series resistance of the stacked capacitor that the 7th execution mode is relevant is set to desirable value, so, can be easily and precision carry out the control of equivalent series resistance well.
In addition, in the laminate 1 of the stacked capacitor that the 7th execution mode is relevant, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 36 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 32 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 35 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 35 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 32 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 36 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.
On the other hand, in the laminate 1 of the relevant stacked capacitor of the 7th execution mode, with respect to the center M on stacked direction, with the symmetrical position of the 2nd internal electrode 41 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 45 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 2nd internal electrode 42 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 42 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 2nd internal electrode 45 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 41 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.
Therefore, situation about will install with respect to substrate etc. with respect to which face among 2 side 1e, the 1f of the stacked direction of laminate 1 no matter, the length of the current path that forms through internal electrode in waiting between the land pattern on the substrate all is difficult to change.Therefore, in the relevant stacked capacitor of the 7th execution mode, the fluctuation of the equivalent series inductance that is caused by installation direction is suppressed.
In addition, the 1st termination electrode 3 is formed on, on the side 1a in the side parallel, that extend in the longitudinal direction with the stacked direction of the laminate 1 of rectangular shape, the 2nd termination electrode 5 is formed on, with in the parallel side of the stacked direction of laminate 1, extend in the longitudinal direction and the side 1b relative with the side 1a that has formed the 1st termination electrode 3 on.Thus, magnetic field can be reduced, the purpose that in the relevant stacked capacitor of the 7th execution mode, reduces equivalent series inductance can be reached by the electric current generation of flowing through the 1st and the 2nd internal electrode 31~36,41~45.
(the 8th execution mode)
The structure of the stacked capacitor that the 8th execution mode is relevant is described with reference to Figure 13.The difference of the stacked capacitor that the stacked capacitor that the 8th execution mode is relevant is relevant with the 5th execution mode is, is formed with otch on the 1st and the 2nd internal electrode 31~36,41~45.Figure 13 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 8th execution mode.
The stacked capacitor that the 8th execution mode is relevant, omit its diagram, but the 1st termination electrode 3 that its stacked capacitor C1 relevant with the 1st execution mode is same, comprises laminate 1, form on this laminate 1, the 2nd termination electrode 5 that on identical laminate 1, forms and, the 1st and the 2nd bonding conductor 7,9.
In the 1st internal electrode 31~36,, be formed with otch S11~S16 with from the next door of conductor introduction 51~56 and the 1st internal electrode 31~36 coupling parts, to the mode that the length direction of the 1st internal electrode 31~36 extends.Therefore, otch S11~S16 be formed into into, in each the 1st internal electrode 31~36, electric current oppositely flows through mutually and clips otch S11~S16 respectively and relative zone.
In the 2nd internal electrode 41~45,, be formed with otch S21~S25 with from the next door of conductor introduction 61~65 and the 2nd internal electrode 41~45 coupling parts, to the mode that the length direction of the 2nd internal electrode 41~45 extends.Therefore, otch S21~S25 be formed into into, in each the 2nd internal electrode 41~45, electric current oppositely flows through mutually and clips otch S21~S25 respectively and relative zone.
In having formed the 1st and the 2nd internal electrode 31~36,41~45 of otch S11~S16, S21~S25, because electric current oppositely flows through mutually in the zone relative clipping otch S11~S16, S21~S25 respectively, so, result from electric current and cancelled each other in the magnetic field that produces.And in the 1st internal electrode 31~36 that has formed otch and the 2nd internal electrode 41~45, from stacked direction, the direction that flows through of electric current is oppositely.Therefore, result from the magnetic field flowing through the electric current of the 1st internal electrode 31~36 and produce, with result from the magnetic field of flowing through the electric current of the 2nd internal electrode 41~45 and producing and cancelled each other.Therefore, in the relevant stacked capacitor of the 8th execution mode, can reach the purpose that reduces equivalent series inductance.
In addition, in the relevant stacked capacitor of the 8th execution mode, making the number that is directly connected in the 1st internal electrode 31,36 of the 1st termination electrode 3 through conductor introduction 37 is 2, makes its sum that is less than the 1st internal electrode 31~36 (being 6 in the present embodiment).In addition, making the number that is directly connected in the 2nd internal electrode 41,45 of the 2nd termination electrode 5 through conductor introduction 47 is 2, makes its sum that is less than the 2nd internal electrode 41~45 (being 5 in the present embodiment).Thus, the stacked capacitor that the 8th execution mode is relevant is connected in the existing stacked capacitor of corresponding termination electrode than whole internal electrodes through conductor introduction, and equivalent series resistance increases.
As mentioned above, according to present embodiment, since by adjust respectively through conductor introduction 37 be electrically connected on the 1st termination electrode 3 the 1st internal electrode 31,36 number and, be electrically connected on the number of the 2nd internal electrode 41,45 of the 2nd termination electrode 5 through conductor introduction 47, the equivalent series resistance of the stacked capacitor that the 8th execution mode is relevant is set to desirable value, so, can be easily and precision carry out the control of equivalent series resistance well.
In addition, in the laminate 1 of the stacked capacitor that the 8th execution mode is relevant, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 31,36 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 36,31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 respectively.On the other hand, in the laminate 1 of the relevant stacked capacitor of the 8th execution mode, center M with respect to stacked direction, with the symmetrical position of the 2nd internal electrode 41,45 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 45,41 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 respectively.Therefore, situation about will install with respect to substrate etc. with respect to which face among 2 side 1e, the 1f of the stacked direction of laminate 1 no matter, the length of the current path that forms through internal electrode in waiting between the land pattern on the substrate all is difficult to change.Therefore, in the relevant stacked capacitor of the 8th execution mode, the fluctuation of the equivalent series inductance that is caused by installation direction is suppressed.
In addition, the 1st termination electrode 3 is formed on, on the side 1a in the side parallel, that extend in the longitudinal direction with the stacked direction of the laminate 1 of rectangular shape, the 2nd termination electrode 5 is formed on, with in the parallel side of the stacked direction of laminate 1, extend in the longitudinal direction and the side 1b relative with the side 1a that forms the 1st termination electrode 3 on.Thus, magnetic field can be reduced, the purpose that in the relevant stacked capacitor of the 8th execution mode, reduces equivalent series inductance can be reached by the electric current generation of flowing through the 1st and the 2nd internal electrode 31~36,41~45.
In addition, there is no need on whole internal electrodes, to form otch, for example, also can on the 1st and the 2nd internal electrode 31,36,41,45 that is electrically connected on the 1st and the 2nd termination electrode 3,5 through conductor introduction 37,47, not form otch.But,, in these internal electrodes 31,36,41,45, result from electric current and can be cancelled out each other in the magnetic field that produces by on the 1st and the 2nd internal electrode 31,36,41,45, forming otch.Therefore, can reach the purpose that further is reduced in the equivalent series inductance in the stacked capacitor.
(the 9th execution mode)
The structure of the stacked capacitor C2 that the 9th execution mode is relevant is described with reference to Figure 14 and Figure 15.Figure 14 is the stereogram of the relevant stacked capacitor of the 9th execution mode.Figure 15 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 9th execution mode.
Stacked capacitor C2, the 1st and the 2nd termination electrode 3,5 that as shown in figure 14, comprises laminate 1, on this laminate 1, forms.
The 1st termination electrode 3 is formed on the side 1a in the side parallel with the stacked direction described later of laminate 1, that extend in the longitudinal direction.The 2nd termination electrode 5 is formed on, with in the parallel side of the stacked direction described later of laminate 1, extend in the longitudinal direction and the side 1b relative with the side 1a that forms the 1st termination electrode 3 on.The 1st termination electrode 3 and the 2nd termination electrode 5 mutual electric insulations.
Each the 1st internal electrode 31~34 is shape in the form of a substantially rectangular.The 1st internal electrode 31~34 is respectively formed at, from laminate 1 dielectric layer 11~18,22 stacked direction (below, abbreviate " stacked direction " as.) parallel side rises, has on the position of predetermined distance.On each the 1st internal electrode 31~34, be formed with opening 31a~34a in the mode of exposing dielectric layer 11,13,15,17.On each dielectric layer 11,13,15,17, the inner conductor 71~74 of collar (rand) shape is positioned at, corresponding on the zone of the opening 31a~34a that forms on the 1st internal electrode 31~34.In addition, to clip dielectric layer 22 adjacent on stacked direction for the side 1e of the 1st internal electrode 31 and laminate 1.
Each the 2nd internal electrode 41~44 rectangular shaped.The 2nd internal electrode 41~44 is respectively formed at, from the side parallel with the stacked direction the laminate 1, have on the position of predetermined distance.On each the 2nd internal electrode 41~44, be formed with opening 41a~44a in the mode of exposing dielectric layer 12,14,16,18.On each dielectric layer 12,14,16,18, the inner conductor 81~84 of collar shape is positioned at, corresponding on the zone of the opening 41a~44a that forms on the 2nd internal electrode 41~44.In addition, to clip dielectric layer 18 adjacent on stacked direction for the side 1f of the 2nd internal electrode 44 and laminate 1.
On the position in dielectric layer 11, be formed with the via conductors 91a, the 91b that on thickness direction, connect dielectric layer 11 respectively corresponding to inner conductor 81 and inner conductor 71.Via conductors 91a is electrically connected on the 1st internal electrode 31.Via conductors 91b is electrically connected on inner conductor 71.Via conductors 91a under the stacked state of dielectric layer 11,12, is electrically connected with inner conductor 81.Via conductors 91b under the stacked state of dielectric layer 11,12, is electrically connected with the 2nd internal electrode 41.
On the position in dielectric layer 12, be formed with the via conductors 92a, the 92b that on thickness direction, connect dielectric layer 12 respectively corresponding to inner conductor 81 and inner conductor 72.Via conductors 92a is electrically connected on inner conductor 81.Via conductors 92b is electrically connected on the 2nd internal electrode 41.Via conductors 92a under the stacked state of dielectric layer 12,13, is electrically connected with the 1st internal electrode 32.Via conductors 92b under the stacked state of dielectric layer 12,13, is electrically connected with inner conductor 72.
On the position in dielectric layer 13, be formed with the via conductors 93a, the 93b that on thickness direction, connect dielectric layer 13 respectively corresponding to inner conductor 82 and inner conductor 72.Via conductors 93a is electrically connected on the 1st internal electrode 32.Via conductors 93b is electrically connected on inner conductor 72.Via conductors 93a under the stacked state of dielectric layer 13,14, is electrically connected with inner conductor 82.Via conductors 93b under the stacked state of dielectric layer 13,14, is electrically connected with the 2nd internal electrode 42.
On the position in dielectric layer 14, be formed with the via conductors 94a, the 94b that on thickness direction, connect dielectric layer 14 respectively corresponding to inner conductor 82 and inner conductor 73.Via conductors 94a is electrically connected on inner conductor 82.Via conductors 94b is electrically connected on the 2nd internal electrode 42.Via conductors 94a under the stacked state of dielectric layer 14,15, is electrically connected with the 1st internal electrode 33.Via conductors 94b under the stacked state of dielectric layer 14,15, is electrically connected with inner conductor 73.
On the position in dielectric layer 15, be formed with the via conductors 95a, the 95b that on thickness direction, connect dielectric layer 15 respectively corresponding to inner conductor 83 and inner conductor 73.Via conductors 95a is electrically connected on the 1st internal electrode 33.Via conductors 95b is electrically connected on inner conductor 73.Via conductors 95a under the stacked state of dielectric layer 15,16, is electrically connected with inner conductor 83.Via conductors 95b under the stacked state of dielectric layer 15,16, is electrically connected with the 2nd internal electrode 43.
On the position in dielectric layer 16, be formed with the via conductors 96a, the 96b that on thickness direction, connect dielectric layer 16 respectively corresponding to inner conductor 83 and inner conductor 74.Via conductors 96a is electrically connected on inner conductor 83.Via conductors 96b is electrically connected on the 2nd internal electrode 43.Via conductors 96a under the stacked state of dielectric layer 16,17, is electrically connected with the 1st internal electrode 34.Via conductors 96b under the stacked state of dielectric layer 16,17, is electrically connected with inner conductor 74.
On the position in dielectric layer 17, be formed with the via conductors 97a, the 97b that on thickness direction, connect dielectric layer 17 respectively corresponding to inner conductor 84 and inner conductor 74.Via conductors 97a is electrically connected on the 1st internal electrode 34.Via conductors 97b is electrically connected on inner conductor 74.Via conductors 97a under the stacked state of dielectric layer 17,18, is electrically connected with inner conductor 84.Via conductors 97b under the stacked state of dielectric layer 17,18, is electrically connected with the 2nd internal electrode 44.
By stacked dielectric layer 11~17, via conductors 91a~97a is set to roughly linearity simultaneously on stacked direction, by the electrical path that is electrically connected to form mutually.The 1st internal electrode 31~34, via through holes conductor 91a~97a and inner conductor 81~84 are electrically connected mutually.
The 1st internal electrode 31 is electrically connected on the 1st termination electrode 3 through conductor introduction 37.Thus, the 1st internal electrode 32~34 also becomes the state that is electrically connected on the 1st termination electrode 3, and the 1st internal electrode 31~34 becomes the state that is connected in parallel.Conductor introduction 37 be formed into into, become one with the 1st internal electrode 31, and, stretch out from the 1st internal electrode 31 in mode in the face of side 1a in the side parallel, that extend in the longitudinal direction with the stacked direction of laminate 1.
Via conductors 91b~97b, 91a~97a is same with via conductors, is set to roughly linearity simultaneously by stacked dielectric layer 11~17 on stacked direction, by the electrical path that is electrically connected to form mutually.The 2nd internal electrode 41~44 via through holes conductor 91b~97b and inner conductor 71~74 are electrically connected mutually.
The 2nd internal electrode 44 is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.Thus, the 2nd internal electrode 41~43 also becomes the state that is electrically connected on the 2nd termination electrode 5, and the 2nd internal electrode 41~44 becomes the state that is connected in parallel.Conductor introduction 47 be formed into into, become one with the 2nd internal electrode 44, and with in the face of with the parallel side of the stacked direction of laminate 1 in, extend in the longitudinal direction and the mode of the side 1b relative with the side 1a that forms the 1st termination electrode 3, stretch out from the 2nd internal electrode 44.
In stacked capacitor C2, making the number that is directly connected in the 1st internal electrode 31 of the 1st termination electrode 3 through conductor introduction 37 is 1, makes its sum that is less than the 1st internal electrode 31~34 (being 4 in the present embodiment).In addition, making the number that is directly connected in the 2nd internal electrode 44 of the 2nd termination electrode 5 through conductor introduction 47 is 1, makes its sum that is less than the 2nd internal electrode 41~44 (being 4 in the present embodiment).In addition, via conductors 91a~97a becomes the state that is connected in series in the 1st termination electrode 3, and the combined resistance composition of via conductors 91a~97a becomes bigger.In addition, via conductors 91b~97b also becomes the state that is connected in series in the 2nd termination electrode 5, and the combined resistance composition of via conductors 91b~97b becomes bigger.Thus, stacked capacitor C2 compares through the existing stacked capacitor that conductor introduction is connected in corresponding termination electrode with whole internal electrodes, and equivalent series resistance increases.
As mentioned above, according to present embodiment, since by adjust respectively through conductor introduction 37 be electrically connected on the 1st termination electrode 3 the 1st internal electrode 31 number and, be electrically connected on the number of the 2nd internal electrode 44 of the 2nd termination electrode 5 through conductor introduction 47, the equivalent series resistance of stacked capacitor C2 is set to desirable value, so, can be easily and precision carry out the control of equivalent series resistance well.
In addition, in the present embodiment, for being connected in parallel, the 2nd internal electrode 41~44 is each other for being connected in parallel each other for the 1st internal electrode 31~34.Thus, even fluctuate in the resistance value of each the 1st internal electrode 31~34 and Ge Di 2 internal electrodes 41~44, the influence of the equivalent series resistance to stacked capacitor C2 in all is also few, can suppress the reduction of the control precision of equivalent series resistance.
In addition, in the laminate 1 of stacked capacitor C2, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.On the other hand, in the laminate 1 of stacked capacitor C2, with respect to the center M on stacked direction, with the symmetrical position of the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.Therefore, situation about will install with respect to substrate etc. with respect to which face among 2 side 1e, the 1f of the stacked direction of laminate 1 no matter, the length of the current path that forms through internal electrode during the land pattern on the substrate is asked and waited also is difficult to variation.Therefore, in the relevant stacked capacitor C2 of the 9th execution mode, the fluctuation of the equivalent series inductance that is caused by installation direction is suppressed.
In addition, the 1st termination electrode 3 is formed on the side 1a in the side parallel with the stacked direction of the laminate 1 of rectangular shape, that extend in the longitudinal direction, the 2nd termination electrode 5 be formed on the parallel side of the stacked direction of laminate 1 in, extend in the longitudinal direction and the side 1b relative with the side 1a that is formed with the 1st termination electrode 3 on.Thus, magnetic field can be reduced, the purpose that in stacked capacitor C2, reduces equivalent series inductance can be reached by the electric current generation of flowing through the 1st and the 2nd internal electrode 31~34,41~44.
(the 10th execution mode)
The structure of the stacked capacitor that the 10th execution mode is relevant is described with reference to Figure 16.The difference of the stacked capacitor C2 that the stacked capacitor that the 10th execution mode is relevant is relevant with the 9th execution mode is to be connected in the position on stacked direction of the 1st and the 2nd internal electrode 33,42 of termination electrode 3,5 through conductor introduction 37,47.Figure 16 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 10th execution mode.
The stacked capacitor that the 10th execution mode is relevant, omit its diagram, but the 1st termination electrode 3 that its stacked capacitor C2 relevant with the 9th execution mode is same, comprises laminate 1, form on this laminate 1 and, the 2nd termination electrode 5 that on identical laminate 1, forms.
In the relevant stacked capacitor of the 10th execution mode, as shown in figure 16, in 4 the 1st internal electrodes 31~34 from the 1st internal electrode 31 downward several the 3rd the 1st internal electrodes 33, be electrically connected on the 1st termination electrode 3 through conductor introduction 37.Thus, the 1st internal electrode 31,32,34 also becomes the state that is electrically connected on the 1st termination electrode 3, and the 1st internal electrode 31~34 becomes the state that is connected in parallel.Conductor introduction 37 be formed into into, become one with the 1st internal electrode 33, and, stretch out from the 1st internal electrode 33 in mode in the face of side 1a in the side parallel, that extend in the longitudinal direction with the stacked direction of laminate 1.
Among 4 the 2nd internal electrodes 41~44 from the 2nd internal electrode 41, several the 2nd the 2nd internal electrodes 42 downwards, be electrically connected on the 2nd termination electrode 5 through conductor introduction 47.Thus, the 2nd internal electrode 41,43,44 also becomes the state that is electrically connected on the 2nd termination electrode 5, and the 2nd internal electrode 41~44 becomes the state that is connected in parallel.Conductor introduction 47 be formed into into, become one with the 2nd internal electrode 42, and with in the face of with the parallel side of the stacked direction of laminate 1 in, extend in the longitudinal direction and the mode of the side 1b relative with the side 1a that is formed with the 1st termination electrode 3, stretch out from the 2nd internal electrode 42.
In the relevant stacked capacitor of the 10th execution mode, making the number that is directly connected in the 1st internal electrode 33 of the 1st termination electrode 3 through conductor introduction 37 is 1, makes its sum that is less than the 1st internal electrode 31~34 (being 4 in the present embodiment).In addition, making the number that is directly connected in the 2nd internal electrode 42 of the 2nd termination electrode 5 through conductor introduction 47 is 1, makes its sum that is less than the 2nd internal electrode 41~44 (being 4 in the present embodiment).Thus, the stacked capacitor that the 10th execution mode is relevant is compared through the existing stacked capacitor that conductor introduction is connected in corresponding termination electrode with whole internal electrodes, and equivalent series resistance increases.
In addition, the resistance components of via conductors 91a~97a is that boundary is divided into the 1st internal electrode 33, more be positioned at than the 1st internal electrode 33 stacked direction a side via conductors 91a~94a the combined resistance composition and more be positioned at the combined resistance composition of via conductors 95a~97a of the opposite side of stacked direction than the 1st internal electrode 33.The combined resistance composition of via conductors 91a~94a and the combined resistance composition of via conductors 95a~97a become with respect to the 1st termination electrode 3 and to be connected in parallel.In addition, the resistance components of via conductors 91b~97b is that boundary is divided into the 2nd internal electrode 42, more be positioned at than the 2nd internal electrode 42 stacked direction a side via conductors 91b~93b the combined resistance composition and more be positioned at the combined resistance composition of via conductors 94b~97b of the opposite side of stacked direction than the 2nd internal electrode 42.The combined resistance composition of via conductors 91b~93b and the combined resistance composition of via conductors 94b~97b become with respect to the 2nd termination electrode 5 and to be connected in parallel.Therefore, the stacked capacitor that the 10th execution mode is relevant, than the relevant stacked capacitor C2 of the 9th execution mode that via conductors 91a~97a, 91b~97b are connected in series respectively, equivalent series resistance is littler.
As mentioned above, according to present embodiment, since by adjust respectively through conductor introduction 37 be electrically connected on the 1st termination electrode 3 the 1st internal electrode 33 in the position on the stacked direction and, be electrically connected on the position on stacked direction of the 2nd internal electrode 42 of the 2nd termination electrode 5 through conductor introduction 47, the equivalent series resistance of the stacked capacitor that the 10th execution mode is relevant is set to desirable value, so, can be easily and precision carry out the control of equivalent series resistance well.
In addition, in the laminate 1 of the stacked capacitor that the 10th execution mode is relevant, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 33 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 2nd internal electrode 42 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.On the other hand, the 10th execution mode relevant in the laminate 1 of stacked capacitor, center M with respect to stacked direction, with the symmetrical position of the 2nd internal electrode 42 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 1st internal electrode 33 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.Therefore, situation about will install with respect to substrate etc. with respect to which face among 2 side 1e, the 1f of the stacked direction of laminate 1 no matter, the length of the current path that forms through internal electrode in waiting between the land pattern on the substrate all is difficult to change.Therefore, in the relevant stacked capacitor of the 10th execution mode, the fluctuation of the equivalent series inductance that is caused by installation direction is suppressed.
In addition, the 1st termination electrode 3 is formed on the side 1a in the side parallel with the stacked direction of the laminate 1 of rectangular shape, that extend in the longitudinal direction, the 2nd termination electrode 5 be formed on the parallel side of the stacked direction of laminate 1 in, length direction extend and the side 1b relative with the side 1a that is formed with the 1st termination electrode 3 on.Thus, magnetic field can be reduced, the purpose that in the relevant stacked capacitor of the 10th execution mode, reduces equivalent series inductance can be reached by the electric current generation of flowing through the 1st and the 2nd internal electrode 31~34,41~44.
(the 11st execution mode)
The structure of the stacked capacitor that the 11st execution mode is relevant is described with reference to Figure 17.The difference of the stacked capacitor C2 that the stacked capacitor that the 11st execution mode is relevant is relevant with the 9th execution mode is to be connected in the number of the 1st and the 2nd internal electrode 31,34,41,44 of termination electrode 3,5 through conductor introduction 37,47.Figure 17 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 11st execution mode.
The stacked capacitor that the 11st execution mode is relevant, omit its diagram, but the 1st termination electrode 3 that its stacked capacitor C2 relevant with the 9th execution mode is same, comprises laminate 1, form on this laminate 1 and, the 2nd termination electrode 5 that on identical laminate 1, forms.
In the relevant stacked capacitor of the 11st execution mode, as shown in figure 17,2 the 1st internal electrodes 31,34 in 4 the 1st internal electrodes 31~34 are electrically connected on the 1st termination electrode 3 through conductor introduction 37.Thus, the 1st internal electrode 32,33 also becomes the state that is electrically connected on the 1st termination electrode 3, and the 1st internal electrode 31~34 becomes the state that is connected in parallel.Conductor introduction 37 be formed into into, become one with each the 1st internal electrode 31,34, and, stretch out from the 1st internal electrode 31,34 in mode in the face of side 1a in the side parallel, that extend in the longitudinal direction with the stacked direction of laminate 1.
2 the 2nd internal electrodes 41,44 in 4 the 2nd internal electrodes 41~44 are electrically connected on the 2nd termination electrode 5 through conductor introduction 47.Thus, the 2nd internal electrode 42,43 also becomes the state that is electrically connected on the 2nd termination electrode 5, and the 2nd internal electrode 41~44 becomes the state that is connected in parallel.Conductor introduction 47 be formed into into, become one with each the 2nd internal electrode 41,44, and with in the face of with the parallel side of the stacked direction of laminate 1 in, extend in the longitudinal direction and the mode of the side 1b relative with the side 1a that is formed with the 1st termination electrode 3, stretch out from the 2nd internal electrode 41,44 respectively.
In the relevant stacked capacitor of the 11st execution mode, making the number that is directly connected in the 1st internal electrode 31,34 of the 1st termination electrode 3 through conductor introduction 37 is 2, makes it be less than the sum of the 1st internal electrode 31~34.In addition, making the number that is directly connected in the 2nd internal electrode 41,44 of the 2nd termination electrode 5 through conductor introduction 47 is 2, makes it be less than the sum of the 2nd internal electrode 41~44.Thus, the stacked capacitor that the 11st execution mode is relevant is compared through the existing stacked capacitor that conductor introduction is connected in corresponding termination electrode with whole internal electrodes, and equivalent series resistance increases.
The stacked capacitor C2 that the stacked capacitor that the 11st execution mode is relevant is correlated with than the 9th execution mode, the number of the 1st internal electrode 31,34 that is directly connected in the 1st termination electrode 3 through conductor introduction 37 is more, and these conductor introduction 37 is connected in parallel with respect to the 1st termination electrode 3.In addition, the number of the 2nd internal electrode 41,44 that is directly connected in the 2nd termination electrode 5 through conductor introduction 47 is more, and these conductor introductions 47 are connected in parallel with respect to the 2nd termination electrode 5.Therefore, the equivalent series resistance of the stacked capacitor that the 11st execution mode is relevant is than the relevant stacked capacitor C2 of the 9th execution mode, and equivalent series resistance diminishes.
As mentioned above, according to present embodiment, since by adjust respectively through conductor introduction 37 be electrically connected on the 1st termination electrode 3 the 1st internal electrode 31,34 number and, be electrically connected on the number of the 2nd internal electrode 41,44 of the 2nd termination electrode 5 through conductor introduction 47, the equivalent series resistance of the stacked capacitor that the 11st execution mode is relevant is set to desirable value, so, can be easily and precision carry out the control of equivalent series resistance well.
In addition, in the laminate 1 of the stacked capacitor that the 11st execution mode is relevant, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 34 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 2nd internal electrode 41 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.On the other hand, in the laminate 1 of the stacked capacitor that the 11st execution mode is relevant, with respect to the center M on stacked direction, with the symmetrical position of the 2nd internal electrode 41 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 1st internal electrode 34 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.Therefore, situation about will install with respect to substrate etc. with respect to which face among 2 side 1e, the 1f of the stacked direction of laminate 1 no matter, the length of the current path that forms through internal electrode in waiting between the land pattern on the substrate all is difficult to change.Therefore, in the relevant stacked capacitor of the 11st execution mode, the fluctuation of the equivalent series inductance that is caused by installation direction is suppressed.
In addition, the 1st termination electrode 3 be formed in the side parallel with the stacked direction of the laminate 1 of rectangular shape, on the side 1a that length direction extends, the 2nd termination electrode 5 be formed on the parallel side of the stacked direction of laminate 1 in, length direction extend and the side 1b relative with the side 1a that is formed with the 1st termination electrode 3 on.Thus, magnetic field can be reduced, the purpose that in the relevant stacked capacitor of the 11st execution mode, reduces equivalent series inductance can be reached by the electric current generation of flowing through the 1st and the 2nd internal electrode 31~34,41~44.
(the 12nd execution mode)
The structure of the stacked capacitor that the 12nd execution mode is relevant is described with reference to Figure 18.The difference of the stacked capacitor C2 that the stacked capacitor that the 12nd execution mode is relevant is relevant with the 9th execution mode is, is formed with otch on the 1st and the 2nd internal electrode 31~34,41~44.Figure 18 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 12nd execution mode.
The stacked capacitor that the 12nd execution mode is relevant, omit its diagram, but the 1st termination electrode 3 that its stacked capacitor C2 relevant with the 9th execution mode is same, comprises laminate 1, form on this laminate 1 and, the 2nd termination electrode 5 that on identical laminate 1, forms.
In the 1st internal electrode 31~34, mode so that extend on the next door of the part that is connected with the 1st internal electrode 31~34 from the end limit of the 1st internal electrode 31~34 relative with the side 1d of laminate 1, to via conductors 91a~97a is formed with otch S11~S14.Therefore, otch S11~S14 be formed into into, in each the 1st internal electrode 31~34, electric current oppositely flows through mutually and clips otch S11~S14 respectively and relative zone.
In the 2nd internal electrode 41~44, mode so that extend on the next door of the part that is connected with the 2nd internal electrode 41~44 from the end limit of the 2nd internal electrode 41~44 relative with the side 1c of laminate 1, to via conductors 91b~97b is formed with otch S21~S24.Therefore, otch S21~S24 be formed into into, in each the 2nd internal electrode 41~44, electric current oppositely flows through mutually and clips otch S21~S24 respectively and relative zone.
Because in having formed the 1st and the 2nd internal electrode 31~34,41~44 of otch S11~S14, S21~S24, electric current oppositely flows through mutually in the relative zone clipping otch S11~S14, S21~S24 respectively, so, result from electric current and cancelled each other in the magnetic field that produces.And in the 1st internal electrode 31~34 that has formed otch and the 2nd internal electrode 41~44, from stacked direction, the direction that flows through of electric current is oppositely.Therefore, result from the magnetic field flowing through the electric current of the 1st internal electrode 31~34 and produce, with result from the magnetic field of flowing through the electric current of the 2nd internal electrode 41~44 and producing and cancelled each other.Therefore, in the relevant stacked capacitor of the 12nd execution mode, can reach the purpose that reduces equivalent series inductance.
In addition, in the relevant stacked capacitor of the 12nd execution mode, making the number that is directly connected in the 1st internal electrode 31 of the 1st termination electrode 3 through conductor introduction 37 is 1, makes its sum that is less than the 1st internal electrode 31~34 (being 4 in the present embodiment).In addition, making the number that is directly connected in the 2nd internal electrode 44 of the 2nd termination electrode 5 through conductor introduction 47 is 1, makes its sum that is less than the 2nd internal electrode 41~44 (being 4 in the present embodiment).Thus, the stacked capacitor that the 12nd execution mode is relevant is connected in the existing stacked capacitor of corresponding termination electrode than whole internal electrodes through conductor introduction, and equivalent series resistance increases.
As mentioned above, according to present embodiment, since by adjust respectively through conductor introduction 37 be electrically connected on the 1st termination electrode 3 the 1st internal electrode 31 number and, be electrically connected on the number of the 2nd internal electrode 44 of the 2nd termination electrode 5 through conductor introduction 47, the equivalent series resistance of the stacked capacitor that the 12nd execution mode is relevant is set to desirable value, so, can be easily and precision carry out the control of equivalent series resistance well.
In addition, in the laminate 1 of the stacked capacitor that the 12nd execution mode is relevant, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.On the other hand, in the laminate 1 of the relevant stacked capacitor of the 12nd execution mode, center M with respect to stacked direction, with the symmetrical position of the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.Therefore, situation about will install with respect to substrate etc. with respect to which face among 2 side 1e, the 1f of the stacked direction of laminate 1 no matter, the length of the current path that forms through internal electrode in waiting between the land pattern on the substrate all is difficult to change.Therefore, in the relevant stacked capacitor of the 12nd execution mode, the fluctuation of the equivalent series inductance that is caused by installation direction is suppressed.
In addition, the 1st termination electrode 3 be formed in the side parallel with the stacked direction of the laminate 1 of rectangular shape, on the side 1a that length direction extends, the 2nd termination electrode 5 be formed on the parallel side of the stacked direction of laminate 1 in, length direction extend and the side 1b relative with the side 1a that is formed with the 1st termination electrode 3 on.Thus, magnetic field can be reduced, the purpose that in the relevant stacked capacitor of the 12nd execution mode, reduces equivalent series inductance can be reached by the electric current generation of flowing through the 1st and the 2nd internal electrode 31~34,41~44.
In addition, there is no need on whole internal electrodes, all to be formed with otch, for example, on the 1st and the 2nd internal electrode 31,44 that is electrically connected on the 1st and the 2nd termination electrode 3,5 by conductor introduction 37,47, also can not be formed with otch.And, in these internal electrodes 31,44, result from electric current and cancelled out each other in the magnetic field that produces by on the 1st and the 2nd internal electrode 31,44, forming otch.Therefore, can reach the purpose that further is reduced in the equivalent series inductance in the stacked capacitor.
(the 13rd execution mode)
The structure of the stacked capacitor that the 13rd execution mode is relevant is described with reference to Figure 19.The difference of the stacked capacitor C2 that the stacked capacitor that the 13rd execution mode is relevant is relevant with the 9th execution mode is: the 1st internal electrode is, the 1st internal electrode that is connected with the 1st termination electrode, the internal electrode that exists on respect to symmetrical position, the center on the stacked direction at laminate; The 2nd internal electrode is, the 2nd internal electrode that is connected with the 2nd termination electrode, with the internal electrode that exists on respect to symmetrical position, the center on the stacked direction at laminate.Figure 19 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 13rd execution mode.
The stacked capacitor that the 13rd execution mode is relevant, omit its diagram, but the 1st termination electrode 3 that its stacked capacitor C2 relevant with the 9th execution mode is same, comprises laminate 1, form on this laminate 1 and, the 2nd termination electrode 5 that on identical laminate 1, forms.
Each the 1st internal electrode 31~36 is shape in the form of a substantially rectangular.The 1st internal electrode 31~36 is respectively formed at, from laminate 1 dielectric layer 11~22 stacked direction (below, abbreviate " stacked direction " as.) parallel side rises, has on the position of predetermined distance.On each the 1st internal electrode 31~36, be formed with opening 31a~36a in the mode of exposing dielectric layer 11,13,15,17,19,21.On each dielectric layer 11,13,15,17,19,21, the inner conductor 71~76 of pad shape is positioned at corresponding on the zone of the opening 31a~36a that forms on the 1st internal electrode 31~36.In addition, to clip dielectric layer 22 adjacent on stacked direction for the side 1e of the 1st internal electrode 31 and laminate 1.It is adjacent on stacked direction that the side 1f of the 1st internal electrode 36 and laminate 1 clips dielectric layer 21.
Each the 2nd internal electrode 41~45 rectangular shaped.The 2nd internal electrode 41~45 is respectively formed at from the side parallel with the stacked direction the laminate 1 to have on the position of predetermined distance.On each the 2nd internal electrode 41~45, be formed with opening 41a~45a in the mode of exposing dielectric layer 12,14,16,18,20.On each dielectric layer 12,14,16,18,20, the inner conductor 81~85 of pad shape is positioned at corresponding on the zone of the opening 41a~45a that forms on the 2nd internal electrode 41~45.
The stacked capacitor C2 that via conductors 91a~97a is relevant with the 9th execution mode is same, is set to roughly linearity simultaneously by stacked dielectric layer 11~17 on stacked direction, and is electrically connected mutually.Via conductors 91b~97b also is set to roughly linearity simultaneously by stacked dielectric layer 11~17 on stacked direction, and is electrically connected mutually.
And in the relevant stacked capacitor of the 13rd execution mode, dielectric layer 18~21 is stacked, and via conductors 98a~100a, 98b~100b are set to roughly linearity simultaneously.
That is, on the position in dielectric layer 18, be formed with the via conductors 98a, the 98b that on thickness direction, connect dielectric layer 18 respectively corresponding to inner conductor 84 and inner conductor 75.Via conductors 98a is electrically connected on inner conductor 84.Via conductors 98b is electrically connected on the 2nd internal electrode 44.Under the stacked state of dielectric layer 18,19, via conductors 98a is electrically connected with the 1st internal electrode 35.Under the stacked state of dielectric layer 18,19, via conductors 98b is electrically connected with inner conductor 75.
On the position in dielectric layer 19, be formed with the via conductors 99a, the 99b that on thickness direction, connect dielectric layer 19 respectively corresponding to inner conductor 85 and inner conductor 75.Via conductors 99a is electrically connected on the 1st internal electrode 35.Via conductors 99b is electrically connected on inner conductor 75.Via conductors 99a dielectric layer 19,20 stacked state under be electrically connected with inner conductor 85.Via conductors 99b dielectric layer 19,20 stacked state under be electrically connected with the 2nd internal electrode 45.
On the position in dielectric layer 20, be formed with the via conductors 100a, the 100b that on thickness direction, connect dielectric layer 20 respectively corresponding to inner conductor 85 and inner conductor 76.Via conductors 100a is electrically connected on inner conductor 85.Via conductors 100b is electrically connected on the 2nd internal electrode 45.Via conductors 100a is electrically connected with the 1st internal electrode 36 under the stacked state of dielectric layer 20,21.Via conductors 100b is electrically connected with inner conductor 76 under the stacked state of dielectric layer 20,21.
Via conductors 91a~100a because dielectric layer 11~20 is stacked, and is set to roughly linearity simultaneously on stacked direction, constitute electrical path by mutual electrical connection.The 1st internal electrode 31~36 via through holes conductor 91a~100a and inner conductor 81~85 are electrically connected mutually.
The 1st internal electrode 31,36 is electrically connected on the 1st termination electrode 3 through conductor introduction 37.Thus, the 1st internal electrode 32~35 also becomes the state that is electrically connected to the 1st termination electrode 3, and the 1st internal electrode 31~36 becomes the state that is connected in parallel.Conductor introduction 37 is formed with the 1st internal electrode 31,36 and becomes one, and in the mode in the face of side 1a in the side parallel with the stacked direction of laminate 1, that extend in the longitudinal direction, stretches out from the 1st internal electrode 31,36.
Via conductors 91b~100b and via conductors 91a~100a are same, are set to roughly linearity by stacked dielectric layer 11~20 simultaneously on stacked direction, by the electrical path that is electrically connected to form mutually.The 2nd internal electrode 41~45 via through holes conductor 91b~100b and inner conductor 71~76 are electrically connected mutually.
The 2nd internal electrode 41,45 is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.Thus, the 2nd internal electrode 42~44 also becomes the state that is electrically connected on the 2nd termination electrode 5, and the 2nd internal electrode 41~45 becomes the state that is connected in parallel.Conductor introduction 47 is formed with the 2nd internal electrode 41,45 and becomes one, and with in the face of with the parallel side of the stacked direction of laminate 1 in, extend in the longitudinal direction and the mode of the side 1b relative with the side 1a that forms the 1st termination electrode 3, stretch out from the 2nd internal electrode 41,45.
In the relevant stacked capacitor of the 13rd execution mode, making the number that is directly connected in the 1st internal electrode 31,36 of the 1st termination electrode 3 through conductor introduction 37 is 2, makes its sum that is less than the 1st internal electrode 31~36 (being 6 in the present embodiment).In addition, making the number that is directly connected in the 2nd internal electrode 41,45 of the 2nd termination electrode 5 through conductor introduction 47 is 2, makes its sum that is less than the 2nd internal electrode 41~45 (being 5 in the present embodiment).Therefore, the stacked capacitor that the 13rd execution mode is relevant is compared through the existing stacked capacitor that conductor introduction is connected in corresponding termination electrode with whole internal electrodes, and equivalent series resistance increases.
As mentioned above, according to present embodiment, since by adjust respectively through conductor introduction 37 be electrically connected on the 1st termination electrode 3 the 1st internal electrode 31,36 number and, be electrically connected on the number of the 2nd internal electrode 41,45 of the 2nd termination electrode 5 through conductor introduction 47, the equivalent series resistance of the stacked capacitor that the 13rd execution mode is relevant is set to desirable value, thus can be easily and precision carry out the control of equivalent series resistance well.
In addition, in the present embodiment, for being connected in parallel, the 2nd internal electrode 41~45 is each other for being connected in parallel each other for the 1st internal electrode 31~36.Thus, even in the resistance value of each the 1st internal electrode 31~36 and Ge Di 2 internal electrodes 41~45, fluctuate, the influence of the equivalent series resistance to the relevant stacked capacitor of the 13rd execution mode in all is also few, and the control precision that can suppress equivalent series resistance reduces.
In addition, in the laminate 1 of the relevant stacked capacitor of the 13rd execution mode, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 36 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 36 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.And in the laminate 1 of the relevant stacked capacitor of the 13rd execution mode, with respect at the center of stacked direction M, with the symmetrical position of the 2nd internal electrode 41 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 45 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.In laminate 1, with respect to the center M of stacked direction, with the symmetrical position of the 2nd internal electrode 45 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 41 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.Therefore, even situation about will install with respect to substrate etc. with respect to which face among 2 side 1e, the 1f of the stacked direction of laminate 1, the length of the current path that forms through internal electrode in waiting between the land pattern on the substrate also is difficult to change.Therefore, in the relevant stacked capacitor of the 13rd execution mode, the equivalent series inductance fluctuation that is caused by installation direction is suppressed.
In addition, the 1st termination electrode 3 be formed in the side parallel with the stacked direction of the laminate 1 of rectangular shape on the side 1a that length direction extends, the 2nd termination electrode 5 be formed on the parallel side of the stacked direction of laminate 1 in, on the relative side 1b of side 1a that length direction extends and forms with the 1st termination electrode 3.Thus, magnetic field can be reduced, the purpose that in the relevant stacked capacitor of the 13rd execution mode, reduces equivalent series inductance can be reached by the electric current generation of flowing through the 1st and the 2nd internal electrode 31~36,41~45.
(the 14th execution mode)
The structure of the stacked capacitor that the 14th execution mode is relevant is described with reference to Figure 20.The difference of the stacked capacitor that the stacked capacitor that the 14th execution mode is relevant is relevant with the 13rd execution mode is, through conductor introduction 37 be connected in the 1st termination electrode 3 the 1st internal electrode 33,34 and, be connected in the position on stacked direction of the 2nd internal electrode 42,44 of the 2nd termination electrode 5 through conductor introduction 47.Figure 20 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 14th execution mode.
The stacked capacitor that the 14th execution mode is relevant, omit its diagram, but the 1st termination electrode 3 that its stacked capacitor C2 relevant with the 9th execution mode is same, comprises laminate 1, form on this laminate 1 and, the 2nd termination electrode 5 that on identical laminate 1, forms.
In the relevant stacked capacitor of the 14th execution mode, as shown in figure 20, in 6 the 1st internal electrodes 31~36 from last the 3rd the 1st internal electrode 33 with from last the 4th the 1st internal electrode 34, be electrically connected on the 1st termination electrode 3 through conductor introduction 37.Thus, the 1st internal electrode 31,32,35,36 also becomes the state that is electrically connected on the 1st termination electrode 3, and the 1st internal electrode 31~36 becomes the state that is connected in parallel.Conductor introduction 37 is formed into to becoming one with the 1st internal electrode 33,34, and in the mode in the face of the side 1a that extends in the longitudinal direction in the side parallel with the stacked direction of laminate 1, stretches out from the 1st internal electrode 33,34.
In the relevant stacked capacitor of the 14th execution mode, as shown in figure 20, in 5 the 2nd internal electrodes 41~45 from last the 2nd the 2nd internal electrode 42 with from last the 4th the 2nd internal electrode 44, be electrically connected on the 2nd termination electrode 5 through conductor introduction 47.Thus, the 2nd internal electrode 41,43,45 also becomes the state that is electrically connected on the 2nd termination electrode 5, and the 2nd internal electrode 41~45 becomes the state that is connected in parallel.Conductor introduction 47 is formed into to becoming one with the 2nd internal electrode 42,44, and with in the face of with the parallel side of the stacked direction of laminate 1 in, extend in the longitudinal direction and the mode of the side 1b relative with side 1a, stretch out from the 2nd internal electrode 42,44.
In the relevant stacked capacitor of the 14th execution mode, making the number that is directly connected in the 1st internal electrode 33,34 of the 1st termination electrode 3 through conductor introduction 37 is 2, makes its sum that is less than the 1st internal electrode 31~36 (being 6 in the present embodiment).In addition, making the number that is directly connected in the 2nd internal electrode 42,44 of the 2nd termination electrode 5 through conductor introduction 47 is 2, makes its sum that is less than the 2nd internal electrode 41~45 (being 5 in the present embodiment).Thus, the stacked capacitor that the 14th execution mode is relevant is compared through the existing stacked capacitor that conductor introduction is connected in corresponding termination electrode with whole internal electrodes, and equivalent series resistance increases.
In addition, if be conceived to the relevant stacked capacitor of the 1st termination electrode 3, the 14 execution modes than the relevant stacked capacitor of the 13rd execution mode, the resistance components of via conductors 91a~100a is to the method for attachment difference of the 1st termination electrode 3.That is, in the relevant stacked capacitor of the 13rd execution mode, the resistance components of via conductors 91a~100a is connected in series with respect to the 1st internal electrode 31,36 respectively.On the other hand, in the relevant stacked capacitor of the 14th execution mode, the resistance components of via conductors 91a~100a is that boundary is separated with the 1st internal electrode 33,34 respectively, and these resistance components are connected in parallel with respect to the 1st termination electrode 3.In addition, if be conceived to the relevant stacked capacitor of the 2nd termination electrode 5, the 14 execution modes than the relevant stacked capacitor of the 13rd execution mode, the resistance components of via conductors 91b~100b is to the method for attachment difference of the 2nd termination electrode 5.That is, in the relevant stacked capacitor of the 13rd execution mode, the resistance components of via conductors 91b~100b is connected in series with respect to the 2nd internal electrode 41,45 respectively.And in the relevant stacked capacitor of the 14th execution mode, the resistance components of via conductors 91b~100b is that boundary is separated with the 2nd internal electrode 42,44 respectively, and these resistance components are connected in parallel with respect to the 2nd termination electrode 5.
Therefore, since the difference of the resistance components of via conductors 91a~100a, 91b~100b, the stacked capacitor that the stacked capacitor that the 14th execution mode is relevant is correlated with than the 13rd execution mode, and equivalent series resistance diminishes.
As mentioned above, according to present embodiment, since by adjust respectively through conductor introduction 37 be electrically connected on the 1st termination electrode 3 the 1st internal electrode 33,34 in the position on the stacked direction and, be electrically connected on the position on stacked direction of the 2nd internal electrode 42,44 of the 2nd termination electrode 5 through conductor introduction 47, the equivalent series resistance of stacked capacitor is set to desirable value, thus can be easily and precision carry out the control of equivalent series resistance well.
In addition, in the laminate 1 of the stacked capacitor that the 14th execution mode is relevant, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 33 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 34 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 34 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 33 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.And in the laminate 1 of the relevant stacked capacitor of the 14th execution mode, center M with respect to stacked direction, with the symmetrical position of the 2nd internal electrode 42 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.In laminate 1, with respect to the center M of stacked direction, with the symmetrical position of the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 42 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.Therefore, even situation about will install with respect to substrate etc. with respect to which face among 2 side 1e, the 1f of the stacked direction of laminate 1, the length of the current path that forms through internal electrode in waiting between the land pattern on the substrate all is difficult to change.Therefore, in the relevant stacked capacitor of the 14th execution mode, suppressed the fluctuation of the equivalent series inductance that causes by installation direction.
In addition, the 1st termination electrode 3 be formed in the side parallel with the stacked direction of the laminate 1 of rectangular shape on the side 1a that length direction extends, the 2nd termination electrode 5 be formed on the parallel side of the stacked direction of laminate 1 in, on the relative side 1b of side 1a that length direction extends and forms with the 1st termination electrode 3.Thus, magnetic field can be reduced, the purpose that in the relevant stacked capacitor of the 14th execution mode, reduces equivalent series inductance can be reached by the electric current generation of flowing through the 1st and the 2nd internal electrode 31~36,41~45.
(the 15th execution mode)
The structure of the stacked capacitor that the 15th execution mode is relevant is described with reference to Figure 21.The difference of the stacked capacitor that the stacked capacitor that the 15th execution mode is relevant is relevant with the 13rd execution mode is, is connected in the number of the 1st and the 2nd internal electrode 31,32,35,36,41,42,44,45 of termination electrode 3,5 through conductor introduction 37,47.Figure 21 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 15th execution mode.
The stacked capacitor that the 15th execution mode is relevant, omit its diagram, but the 1st termination electrode 3 that its stacked capacitor C2 relevant with the 9th execution mode is same, comprises laminate 1, form on this laminate 1 and, the 2nd termination electrode 5 that on identical laminate 1, forms.
In the relevant stacked capacitor of the 15th execution mode, as shown in figure 21,4 the 1st internal electrodes 31,32,35,36 in 6 the 1st internal electrodes 31~36 are electrically connected on the 1st termination electrode 3 through conductor introduction 37.Because the 1st internal electrode 31~36 is electrically connected mutually through the 1st bonding conductor 7, so the 1st internal electrode 33,34 also becomes the state that is electrically connected on the 1st termination electrode 3 through bonding conductor 7, the 1st internal electrode 31~36 becomes the state that is connected in parallel.Conductor introduction 37 is formed into to becoming one with each the 1st internal electrode 31,32,35,36, and, stretch out from the 1st internal electrode 31,32,35,36 in mode in the face of side 1a in the side parallel, that extend in the longitudinal direction with the stacked direction of laminate 1.
4 the 2nd internal electrodes 41,42,44,45 in 5 the 2nd internal electrodes 41~45 are electrically connected on the 2nd termination electrode 5 through conductor introduction 47.Because the 2nd internal electrode 41~45 is electrically connected mutually through the 2nd bonding conductor 9, the 2nd internal electrode 43 also becomes the state that is electrically connected on the 2nd termination electrode 5 through the 2nd bonding conductor 9, and the 2nd internal electrode 41~45 becomes the state that is connected in parallel.Conductor introduction 47 is formed into to becoming one with each the 2nd internal electrode 41,42,44,45, and with in the face of with the parallel side of the stacked direction of laminate 1 in, extend in the longitudinal direction and the mode of the side 1b relative with side 1a, stretch out from the 2nd internal electrode 41,42,44,45.
In the relevant stacked capacitor of the 15th execution mode, making the number that is directly connected in the 1st internal electrode 31,32,35,36 of the 1st termination electrode 3 through conductor introduction 37 is 4, makes it be less than the sum of the 1st internal electrode 31~36.In addition, making the number that is directly connected in the 2nd internal electrode 41,42,44,45 of the 2nd termination electrode 5 through conductor introduction 47 is 4, makes it than the sum of the 2nd internal electrode 41~45 still less.Thus, the stacked capacitor that the 15th execution mode is relevant is connected in the existing stacked capacitor of corresponding termination electrode than whole internal electrodes through conductor introduction, and equivalent series resistance increases.
The stacked capacitor that the 15th execution mode is relevant, than the relevant stacked capacitor of the 13rd execution mode, the number of the 1st internal electrode 31,32,35,36 that is directly connected in the 1st termination electrode 3 through conductor introduction 37 is more, and these conductor introductions 37 are connected in parallel with respect to the 1st termination electrode 3.In addition, the stacked capacitor that the 15th execution mode is relevant, than the relevant stacked capacitor of the 13rd execution mode, the number of the 2nd internal electrode 41,42,44,45 that is directly connected in the 2nd termination electrode 5 through conductor introduction 47 is more, and these conductor introductions 47 are connected in parallel with respect to the 2nd termination electrode 5.Therefore, the equivalent series resistance of the stacked capacitor that the 15th execution mode is relevant diminishes than the equivalent series resistance of the relevant stacked capacitor of the 13rd execution mode.
As mentioned above, according to present embodiment, since by adjust respectively through conductor introduction 37 be electrically connected on the 1st termination electrode 3 the 1st internal electrode 31,32,35,36 number and, be electrically connected on the number of the 2nd internal electrode 41,42,44,45 of the 2nd termination electrode 5 through conductor introduction 47, the equivalent series resistance of the stacked capacitor that the 15th execution mode is relevant is set to desirable value, thus can be easily and precision carry out the control of equivalent series resistance well.
In addition, in the laminate 1 of the stacked capacitor that the 15th execution mode is relevant, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 36 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 32 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 35 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 35 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 32 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 36 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, have the 1st internal electrode 31 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37.
And in the laminate 1 of the relevant stacked capacitor of the 15th execution mode, with respect to the center M on stacked direction, with the symmetrical position of the 2nd internal electrode 41 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 45 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 2nd internal electrode 42 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 2nd internal electrode 44 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 42 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.In laminate 1, with respect to the center M on stacked direction, with the symmetrical position of the 2nd internal electrode 45 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 41 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47.
Therefore, no matter make the situation of installing with respect to substrate etc. with respect to which face among 2 side 1e, the 1f of the stacked direction of laminate 1, the length of the current path that forms through internal electrode in waiting between the land pattern on the substrate all is difficult to change.Therefore, in the relevant stacked capacitor of the 15th execution mode, the fluctuation of the equivalent series inductance that is caused by installation direction is suppressed.
In addition, the 1st termination electrode 3 be formed in the side parallel with the stacked direction of the laminate 1 of rectangular shape on the side 1a that length direction extends, the 2nd termination electrode 5 be formed on the parallel side of the stacked direction of laminate 1 in, length direction extend and the side 1b relative with the side 1a that forms the 1st termination electrode 3 on.Thus, magnetic field can be reduced, the purpose that in the relevant stacked capacitor of the 15th execution mode, reduces equivalent series inductance can be reached by the electric current generation of flowing through the 1st and the 2nd internal electrode 31~36,41~45.
(the 16th execution mode)
The structure of the stacked capacitor that the 16th execution mode is relevant is described with reference to Figure 22.The difference of the stacked capacitor that the stacked capacitor that the 16th execution mode is relevant is relevant with the 13rd execution mode is, forms otch on the 1st and the 2nd internal electrode 31~36,41~45.Figure 22 is the exploded perspective view of the laminate that comprises in the relevant stacked capacitor of the 16th execution mode.
The stacked capacitor that the 16th execution mode is relevant, omit its diagram, but the 1st termination electrode 3 that its stacked capacitor C2 relevant with the 9th execution mode is same, comprises laminate 1, form on this laminate 1 and, the 2nd termination electrode 5 that on identical laminate 1, forms.
In the 1st internal electrode 31~36, mode so that extend on the next door of the part that is connected with the 1st internal electrode 31~36 from the end limit of the 1st internal electrode 31~36 relative with the side 1d of laminate 1, to via conductors 91a~100a is formed with otch S11~S16.Therefore, otch S11~S16 be formed into into, in each the 1st internal electrode 31~36, electric current oppositely flows through mutually and clips otch S11~S16 respectively and relative zone.
In the 2nd internal electrode 41~45, mode so that extend on the next door of the part that is connected with the 2nd internal electrode 41~45 from the end limit of the 2nd internal electrode 41~45 relative with the side 1c of laminate 1, to via conductors 91b~100b is formed with otch S21~S25.Therefore, otch S21~S25 be formed into into, in each the 2nd internal electrode 41~45, electric current oppositely flows through mutually and clips otch S21~S25 respectively and relative zone.
Because in having formed the 1st and the 2nd internal electrode 31~36,41~45 of otch S11~S16, S21~S25, clipping otch S11~S16, S21~S25 respectively in the relative zone, electric current oppositely flows through mutually, so, result from electric current and cancelled each other in the magnetic field that produces.And in the 1st internal electrode 31~36 that has formed otch and the 2nd internal electrode 41~45, from stacked direction, the direction that flows through of electric current is oppositely.Therefore, result from the magnetic field flowing through the electric current of the 1st internal electrode 31~36 and produce, with result from the magnetic field of flowing through the electric current of the 2nd internal electrode 41~45 and producing and cancelled each other.Therefore, in the relevant stacked capacitor of the 16th execution mode, can reach the purpose that reduces equivalent series inductance.
In addition, in the relevant stacked capacitor of the 16th execution mode, making the number that is directly connected in the 1st internal electrode 31,36 of the 1st termination electrode 3 through conductor introduction 37 is 2, makes its sum than the 1st internal electrode 31~36 (being 6 in the present embodiment) still less.In addition, making the number that is directly connected in the 2nd internal electrode 41,45 of the 2nd termination electrode 5 through conductor introduction 47 is 2, makes its sum than the 2nd internal electrode 41~45 (being 5 in the present embodiment) still less.Thus, the stacked capacitor that the 16th execution mode is relevant is connected in the existing stacked capacitor of corresponding termination electrode than whole internal electrodes through conductor introduction, and equivalent series resistance increases.
As mentioned above, according to present embodiment, since by adjust respectively through conductor introduction 37 be electrically connected on the 1st termination electrode 3 the 1st internal electrode 31,36 number and, be electrically connected on the number of the 2nd internal electrode 41,45 of the 2nd termination electrode 5 through conductor introduction 47, the equivalent series resistance of the stacked capacitor that the 16th execution mode is relevant is set to desirable value, thus can be easily and precision carry out the control of equivalent series resistance well.
In addition, in the laminate 1 of the stacked capacitor that the 16th execution mode is relevant, with respect to the center M on stacked direction, with the symmetrical position of the 1st internal electrode 31,36 that is electrically connected on the 1st termination electrode 3 through conductor introduction 37 on, exist be electrically connected on the 1st termination electrode 3 through conductor introduction 37 the 1st internal electrode 36,31 respectively.And in the laminate 1 of the relevant stacked capacitor of the 16th execution mode, center M with respect to stacked direction, with the symmetrical position of the 2nd internal electrode 41,45 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 on, have the 2nd internal electrode 45,41 that is electrically connected on the 2nd termination electrode 5 through conductor introduction 47 respectively.Therefore, situation about will install with respect to substrate etc. with respect to which face among 2 side 1e, the 1f of the stacked direction of laminate 1 no matter, the length of the current path that forms through internal electrode in waiting between the land pattern on the substrate all is difficult to change.Therefore, in the relevant stacked capacitor of the 16th execution mode, the fluctuation of the equivalent series inductance that is caused by installation direction is suppressed.
In addition, the 1st termination electrode 3 be formed in the side parallel with the stacked direction of the laminate 1 of rectangular shape, on the side 1a that length direction extends, the 2nd termination electrode 5 be formed on the parallel side of the stacked direction of laminate 1 in, length direction extend and the side 1b relative with the side 1a that forms the 1st termination electrode 3 on.Thus, magnetic field can be reduced, in the relevant stacked capacitor of the 16th execution mode, the purpose that reduces equivalent series inductance can be reached by the electric current generation of flowing through the 1st and the 2nd internal electrode 31~36,41~45.
In addition, there is no need on whole internal electrodes, all to be formed with otch, for example, also can on the 1st and the 2nd internal electrode 31,36,41,45 that is electrically connected on the 1st and the 2nd termination electrode 3,5 through conductor introduction 37,47, not be formed with otch.But,, in these internal electrodes 31,36,41,45, result from electric current and can be cancelled out each other in the magnetic field that produces by on the 1st and the 2nd internal electrode 31,36,41,45, forming otch.Therefore, in stacked capacitor, can reach the purpose of further reduction equivalent series inductance.
In the 1st~the 16th execution mode, by adjust through conductor introduction 37,47 be directly connected in the 1st termination electrode 3,5 internal electrode number and, position on stacked direction any at least one, the equivalent series resistance of each stacked capacitor is set to desirable value.Consequently, can be easily and precision carry out the control of equivalent series resistance well.
The adjustment of the number of the 1st above-mentioned internal electrode 31~36, can be below lacking 1 number more than 1, than the sum of the 1st internal electrode 31~36, scope in carry out.The adjustment of the number of the 2nd above-mentioned internal electrode 41~45, can be below lacking 1 number more than 1, than the sum of the 2nd internal electrode 41~45, scope in carry out.Be directly connected in the number of the 1st internal electrode of termination electrode 3 through conductor introduction 37, with the number that is directly connected in the 2nd internal electrode of termination electrode 5 through conductor introduction 47, also can be different.
And, also can adjust the number of bonding conductor 7,9 or via conductors 91a~100a, 91b~100b, thereby make the equivalent series resistance of each stacked capacitor be set to desirable value.At this moment, can precision carry out the control of the equivalent series resistance of each stacked capacitor better.
An example of the number of bonding conductor 7,9 is adjusted in expression in Figure 23 and Figure 24.In the stacked capacitor shown in Figure 23 and Figure 24, the number by the 1st and the 2nd bonding conductor 7,9 in respectively that the 1st execution mode is the relevant stacked capacitor is set at 2, and equivalent series resistance is set at desirable value.Figure 23 is the stereogram of the variation of the relevant stacked capacitor of the 1st execution mode.Figure 24 is the exploded perspective view of the laminate that comprises in the variation of the relevant stacked capacitor of the 1st execution mode.The variation of the stacked capacitor that the 1st execution mode shown in Figure 23 is relevant comprises each 2 the 1st and the 2nd bonding conductor 7,9.As shown in figure 24, the 1st internal electrode 31~34 has 2 conductor introductions 51~54 that are connected in bonding conductor 7 respectively.Therefore, be electrically connected by 2 electrical paths between the 1st internal electrode 31~34, also be electrically connected between the 2nd internal electrode 41~45 by 2 electrical paths.
More than, describe in detail preferred embodiment of the present inventionly, but the present invention is not limited to above-mentioned execution mode and variation.For example, the stacked number of the stacked number of dielectric layer 11~22 and the 1st and the 2nd internal electrode 31~36,41~45 is not limited to the number put down in writing in the above-mentioned execution mode.In addition, be directly connected in through conductor introduction 37,47 termination electrode 3,5 internal electrode number and, the position on stacked direction, be not limited to number and the position put down in writing in the above-mentioned execution mode.In addition, the 1st and the 2nd internal electrode also can directly be connected with the 1st and the 2nd bonding conductor without conductor introduction.
From top description as can be known, the present invention obviously can do the change of variety of way.These changes can not be counted as having broken away from of the present invention will the meaning and scope, and for those of ordinary skills, these changes obviously should be considered to be encompassed within the scope of claim of the present invention.
Claims (10)
1. stacked capacitor possesses: alternately laminated a plurality of dielectric layers and the laminate of a plurality of internal electrodes and a plurality of termination electrodes that on described laminate, form,
It is characterized in that,
Described a plurality of termination electrode comprises the 1st and the 2nd termination electrode of mutual electric insulation;
Described a plurality of internal electrode comprises the a plurality of the 1st and the 2nd internal electrode of alternate configurations;
Described a plurality of the 1st internal electrode is electrically connected mutually through bonding conductor;
Described a plurality of the 2nd internal electrode is electrically connected mutually through bonding conductor;
In described a plurality of the 1st internal electrode, more than 1, than the sum of the 1st internal electrode lack 1 number following, the 1st internal electrode, be electrically connected on described the 1st termination electrode through conductor introduction;
In described a plurality of the 2nd internal electrode, more than 1, than the sum of the 2nd internal electrode lack 1 number following, the 2nd internal electrode, be electrically connected on described the 2nd termination electrode through conductor introduction;
With respect to the center on the stacked direction of described laminate, with the symmetrical position of described each the 1st internal electrode that is electrically connected on described the 1st termination electrode through described conductor introduction on, have described the 2nd internal electrode that is electrically connected on described the 2nd termination electrode through described conductor introduction;
With respect to the center on the stacked direction of described laminate, with described each the polar-symmetric position of the 2nd internal electrical that is electrically connected on described the 2nd termination electrode through described conductor introduction on, have described the 1st internal electrode that is electrically connected on described the 1st termination electrode through described conductor introduction.
2. stacked capacitor possesses: alternately laminated a plurality of dielectric layers and the laminate of a plurality of internal electrodes and a plurality of termination electrodes that on described laminate, form,
It is characterized in that,
Described a plurality of termination electrode comprises the 1st and the 2nd termination electrode of mutual electric insulation;
Described a plurality of internal electrode comprises the a plurality of the 1st and the 2nd internal electrode of alternate configurations;
Described a plurality of the 1st internal electrode is electrically connected mutually through bonding conductor;
Described a plurality of the 2nd internal electrode is electrically connected mutually through bonding conductor;
In described a plurality of the 1st internal electrode, more than 1, than the sum of the 1st internal electrode lack 1 number following, the 1st internal electrode, be electrically connected on described the 1st termination electrode through conductor introduction;
In described a plurality of the 2nd internal electrode, more than 1, than the sum of the 2nd internal electrode lack 1 number following, the 2nd internal electrode, be electrically connected on described the 2nd termination electrode through conductor introduction;
With respect to the center on the stacked direction of described laminate, with described each the 1st internal electrode that is electrically connected on described the 1st termination electrode through described conductor introduction under on the symmetrical position, have described the 1st internal electrode that is electrically connected on described the 1st termination electrode through described conductor introduction;
With respect to the center on the stacked direction of described laminate, with the symmetrical position of described each the 2nd internal electrode that is electrically connected on described the 2nd termination electrode through described conductor introduction on, have described the 2nd internal electrode that is electrically connected on described the 2nd termination electrode through described conductor introduction.
3. stacked capacitor as claimed in claim 1 or 2 is characterized in that,
Described a plurality of the 1st internal electrode is electrically connected on described bonding conductor through conductor introduction;
Described a plurality of the 2nd internal electrode is electrically connected on described bonding conductor through conductor introduction;
Described bonding conductor is formed on the surface of described laminate.
4. as each the described stacked capacitor in the claim 1~3, it is characterized in that,
Described bonding conductor is the via conductors that is provided with on the stacked direction of described laminate in described laminate.
5. as each the described stacked capacitor in the claim 1~4, it is characterized in that,
Be formed with otch on the described the 1st and the 2nd internal electrode of at least a portion in the described a plurality of the 1st and the 2nd internal electrode,
Described otch is formed, and in being formed with each the described the 1st and the 2nd internal electrode of this otch, electric current oppositely flows through mutually and clips this otch and relative zone.
6. as each the described stacked capacitor in the claim 1~5, it is characterized in that,
Described laminate is made into roughly rectangular shape;
Described the 1st termination electrode be formed in the side parallel with the stacked direction of described laminate, on the side that length direction extends;
Described the 2nd termination electrode be formed on the parallel side of the stacked direction of described laminate in, length direction extend and the side relative with the described side that forms described the 1st termination electrode on.
7. as each the described stacked capacitor in the claim 1~6, it is characterized in that,
By adjust respectively through described conductor introduction be electrically connected on described the 1st termination electrode described the 1st internal electrode number and, be electrically connected on the number of described the 2nd internal electrode of described the 2nd termination electrode through described conductor introduction, equivalent series resistance is set to desirable value.
8. as each the described stacked capacitor in the claim 1~6, it is characterized in that,
By adjust respectively through described conductor introduction be electrically connected on the stacked direction of described the 1st internal electrode at described laminate of described the 1st termination electrode the position and, be electrically connected on the position on the stacked direction of described the 2nd internal electrode at described laminate of described the 2nd termination electrode through described conductor introduction, equivalent series resistance is set to desirable value.
9. as claim 7 or 8 described stacked capacitors, it is characterized in that,
By adjust respectively further the number that is electrically connected the described bonding conductor between described a plurality of the 1st internal electrodes and, be electrically connected the number of the described bonding conductor between described a plurality of the 2nd internal electrodes, equivalent series resistance is set to desirable value.
10. as each the described stacked capacitor in the claim 7~9, it is characterized in that,
Be connected in parallel between described a plurality of the 1st internal electrode;
Be connected in parallel between described a plurality of the 2nd internal electrode.
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US20060221546A1 (en) | 2006-10-05 |
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TW200701277A (en) | 2007-01-01 |
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